What Europe can learn from France when it comes to quantum computing – Sifted

The French ambition to become a world leader in deeptech is one of Europes worst-kept secrets.

Not only does the country have one of the biggest deeptech funds in Europe, Bpifrance,but more importantly it has the people and the pipeline of talent through a best-in-breed university system, which is helping the country become a hotbed for innovation.

Quantum is one segment of deeptech where the French are leaving the rest of Europe, and in fact most other nations, far behind. The ambition to set up a quantum hub in the Paris region, linking large corporations and startups, is truly impressive and far-reaching.

Not only is the region focusing on nurturing homegrown talents, but they are also actively scouting for overseas companies to set up European headquarters in the cluster. How would we know? Well, we were one of the very few UK companies targeted.

France has always been at the forefront of cryptography and has one of the richest ecosystems for quantum pioneers. That history includes individuals ranging from the winners of the Nobel Prize in Physics, Albert Fert and Serge Haroche, to French National Centre for Scientific Research (CNRS) Gold Medallist Alain Aspects pioneering research on quantum entanglement and quantum simulators.

To build on this, earlier this year the French government announced a 1.8bn strategy to boost research in quantum technologies over five years. This will see public investment in the field increase from 60m to 200m a year.

Not only is investment increasing, but the often overlooked part is that funding is being funnelled into various fields of quantum computing.France recognises that quantum computing is not a homogenous industry and that various aspects require attention outside the development of actual quantum computers.

France is building a frameworkto make the country a key player across the entire quantum ecosystem

For example, one such area is security. Once a functioning quantum computer emerges, the cryptography that is used to secure all data and communications will become obsolete overnight.

Compounding this risk is the harvest now, decrypt later threat. Nefarious hackers might intercept data today and then hold onto it until quantum computers are advanced enough to decrypt it. To tackle this, new encryption methods are being developed that can stand against these new powerful computers, also known as post-quantum cryptography (PQC).

Its clear France recognises this threat, with plans to put 150 million directly to R&D in the field of PQC. This is in addition to the 780 million that is being devoted to developing computing alone, and the 870 million that is being set aside for sensor research, quantum communications and other related technologies.

Taken together, France is building a framework for industrial and research forces to make the country a key player across the entire quantum ecosystem, from computing development to post-quantum security.

So how does the rest of Europe compare? The short answer is that its lagging far behind.

Frances closest competitor is Germany, with its government recently pledging to invest 2bn in quantum computing and related technologies over five years. Thats a larger number than Frances commitment but it appears the scope is to only build a competitive quantum computer in five years while growing a network of companies to develop applications.

France is well on its way to protecting itself against the very real security threats quantum computers will pose

Investments by other individual governments across the rest of Europe are minimal, with many relying on the EUs Quantum Technologies Flagship programme to lead the way. However, with $1.1bn earmarked to cover 27 countries, little attention is being placed beyond computing R&D into adjacent fields like quantum security and communications.

Even if we focus on the security side of the coin, France is well on its way to protecting itself against the very real security threats quantum computers will pose, with the rest of Europe leaving themselves vulnerable.

It is also the case that France, in my opinion, is keeping pace with the traditional leaders the US, China and Canada and even pushing ahead in some areas.

While the US, Canadian and Chinese governments have committed impressive amounts to quantum, much of the focus in these countries is on developing a functioning computer, without recognising that a successful quantum strategy needs to be much broader. For example, although it has now developed a broad security roadmap, the US Department of Homeland Securitys budget for next year makes scant reference to quantum computing and the technology that is going to underpin post-quantum security.

If we measure success in quantum by not only how quickly we can develop such computers, but also how effectively they can be applied and how robust our protection is against the darker side of the technology, then Id argue that France has the worlds most balanced and systemic approach.

France is firmly Europes trailblazing nation; the rest of the continent ought to take note.

Andersen Cheng is CEO of Post-Quantum and Nomidio

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What Europe can learn from France when it comes to quantum computing - Sifted

On the Path to Exascale, Q-Exa Consortium Tightens the Bonds Between Quantum Computers and Traditional Supercomputing – HPCwire

Nov. 15, 2021 During a press conference on Nov. 15, 2021, German Federal Minister for Education and Research Anja Karliczek announced the beginning of the Q-Exa consortium, an ambitious project aimed at accelerating European quantum computing technologies with the assistance of traditional high-performance computing (HPC).

Q-Exa brings together experts from academia and industry to deploy a 20-qbit quantum demonstrator at the end of 2023 and integrate it into the Leibniz Supercomputing Centres (LRZs) HPC ecosystem. LRZ, one of the 3 centers comprising the Gauss Centre for Supercomputing, is partnering with quantum computer hardware company IQM, software developer HQS, and supercomputer manufacturer Atos. The project is funded with 40 million and will run for 3 years.

LRZ Director Prof. Dr. Dieter Kranzlmller indicated that in addition to developing applications for quantum computing, Q-Exa also serves as an important milestone on the path to exascale computingthe next major milestone is traditional HPC, representing a 40-fold increase in supercomputing power from LRZs current flagship computer, SuperMUC-NG.

At LRZ, we are focused on more than just faster computerswe are looking at new ways of computing, and have been developing and implementing our integrated supercomputing architecture, he said. The Q-Exa project fits in perfectly with our goals in that regard, and also serves as a foundational piece to our Quantum Integration Centre and the Munich Quantum Valley. With Q-Exa, we are able to enhance our current large-scale computing resources with this quantum demonstrator.

Kranzlmller also emphasized that by participating in a co-design project with IQM and HQS, LRZ would be able to bring its decades of experience in bringing new computing technologies to science and industry to a new disruptive computing technology, ensuring that these systems are designed with users from academia and industry in mind and that applications can be ported and scaledto take advantage of the promise of quantum computers.

For more information on the Q-Exa project, read the BMBFpress release(in German) or watch thelivestreamof the event.

Source: Gauss Centre for Supercomputing

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On the Path to Exascale, Q-Exa Consortium Tightens the Bonds Between Quantum Computers and Traditional Supercomputing - HPCwire

Atos and NVIDIA to Advance Climate and Healthcare Research With Exascale Computing – HPCwire

Nov. 15, 2021 Atos and NVIDIA today announced the Excellence AI Lab (EXAIL), which brings together scientists and researchers to help advance European computing technologies, education and research.

The labs first research projects will focus on five key areas enabled by advances in high performance computing and AI: climate research, healthcare and genomics, hybridization with quantum computing, edge AI/computer vision and cybersecurity.

Atos will develop an exascale-class BullSequana X supercomputer with NVIDIAs Arm-based Grace CPU, NVIDIAs next-generation GPU, Atos BXI Exascale Interconnect andNVIDIA Quantum-2 InfiniBand networking platform.

Predicting and Addressing Climate Change

In an effort to more accurately predict climate change, researchers from Atos and NVIDIA will run new AI and deep learning models on Europes fastest supercomputer at the Jlich Supercomputing Center. Such giant-scale models can be used to predict the evolution of extreme weather events and their changing behavior due to global warming, and they will benefit greatly from exascale-class computing.

The JUWELS Booster system, based on AtosBullSequana XH2000 platform, with nearly 2.5 exaflops of AI and 3,744NVIDIA A100 Tensor Core GPUsand NVIDIA Quantum InfiniBand networking, will help provide deeper understanding of climate change and more accurate long-term predictions of events, such as hurricanes, extreme precipitation, and heat and cold waves.

Atos is strongly committed to itsdecarbonization objectives, which are to offset all of our residual emissions by 2028 to reach net zero, and to reach the SBTi target to reduce our global carbon emissions under our control and influence by 50 percent by 2025, said Andy Grant, vice president of global sales for HPC, AI and Quantum at Atos. Many leading climate modeling centers, such asMeteo France,DKRZ, KNMI andAEMet, are using our BullSequana supercomputers to run their large weather and climate models, and the current EXAIL announcement is a clear demonstration of our commitment, one year after the creation of ourCenter of Excellence in Weather and Climate Modellingwith ECMWF.

Climate change intensifies and increases the frequency of extreme weather events that disrupt entire regions, costing governments and economies hundreds of billions each year, said Ian Buck, vice president and general manager of Accelerated Computing at NVIDIA. The goal for EXAIL is to advance vital research to address pressing global challenges surrounding climate change.

Accelerating Medical Research With HPC, Quantum and AI

Supercharging medical breakthroughs with computational genomics is revolutionizing drug discovery and healthcare.Atos Life Sciences Center of Excellencehas partnered with 40 leading institutions to leverage HPC, quantum computing and AI to advance medical imaging, genomics and pharmaceuticals. TheNVIDIA Clara healthcare application frameworkprovides supercomputing performance for genomics, healthcare imaging and computational chemistry applications.

EXAIL will harness Atos advanced computing solutions and NVIDIA Clara to help healthcare researchers and providers accelerate drug discovery and design advanced diagnostic solutions using embedded, edge, data center and cloud platforms.

Advancing Quantum Research

Quantum computing holds the potential to solve complex problems in fields like drug discovery, climate research, machine learning, logistics and finance. But much research remains before quantum computers become viable.

AtosQuantum Learning Machine, a quantum software development and simulation appliance for the coming quantum computer era, enables researchers and engineers to develop and experiment with quantum software. It will use NVIDIA GPUs to help dramatically increase the speed and scale of quantum simulations. This will speed the research in quantum algorithms, quantum information science, new quantum processor architectures and hybrid quantum-GPU system architectures.

Accelerating Computer Vision

Using Atos edge appliances, such as itsBullSequana Edgewhich runs onNVIDIA BlueField DPUs, the research teams at EXAIL will work together to accelerate computer vision and 5G wireless infrastructure. Six Atos labs around the world dedicated to computer vision will be equipped with the latestNVIDIA Fleet Command technologyfor secure deployment and management of AI applications across distributed edge infrastructure.

Advancing Zero-Trust Cybersecurity

Furthermore, the EXAIL research teams will develop a new data-center-to-edge, zero-trust cybersecurity platform leveraging theNVIDIA Morpheus open AI framework, as well as new AI models to instantly detect new cybersecurity threats.

About Atos

Atos is a global leader in digital transformation with 107,000 employees and annual revenue of over 11 billion. European number one in cybersecurity, cloud and high performance computing, the Group provides tailored end-to-end solutions for all industries in 71 countries. A pioneer in decarbonization services and products, Atos is committed to a secure and decarbonized digital for its clients. Atos is a SE (Societas Europaea), listed on Euronext Paris and included on the CAC 40 ESG and Next 20 Paris Stock Indexes. Thepurpose of Atosis to help design the future of the information space. Its expertise and services support the development of knowledge, education and research in a multicultural approach and contribute to the development of scientific and technological excellence. Across the world, the Group enables its customers and employees, and members of societies at large to live, work and develop sustainably, in a safe and secure information space.

About NVIDIA

NVIDIAs invention of the GPU in 1999 sparked the growth of the PC gaming market and has redefined modern computer graphics, high performance computing and artificial intelligence. The companys pioneering work in accelerated computing and AI is reshaping trillion-dollar industries, such as transportation, healthcare and manufacturing, and fueling the growth of many others. More information at https://nvidianews.nvidia.com/.

Source: NVIDIA

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Atos and NVIDIA to Advance Climate and Healthcare Research With Exascale Computing - HPCwire

Quantum computing investments up 80 percent since 2018, and there’s new motivation in the space – Oakland News Now

Oakland News Now

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CNBCs Eamon Javers reports on the U.S. drive to lead the race for quantum computing. Javers speaks with IonQ president and CEO, Peter Chapman, and

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Quantum computing investments up 80 percent since 2018, and there's new motivation in the space - Oakland News Now

IBM Launches Its First Quantum Computing Certification | The Info-Tech Brief – Oakland News Now

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The quantum future gets a little closer

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IBM Launches Its First Quantum Computing Certification | The Info-Tech Brief - Oakland News Now

Google AI Blog: Quantum Supremacy Using a Programmable …

This result is the first experimental challenge against the extended Church-Turing thesis, which states that classical computers can efficiently implement any reasonable model of computation. With the first quantum computation that cannot reasonably be emulated on a classical computer, we have opened up a new realm of computing to be explored.

The Sycamore ProcessorThe quantum supremacy experiment was run on a fully programmable 54-qubit processor named Sycamore. Its comprised of a two-dimensional grid where each qubit is connected to four other qubits. As a consequence, the chip has enough connectivity that the qubit states quickly interact throughout the entire processor, making the overall state impossible to emulate efficiently with a classical computer.

The success of the quantum supremacy experiment was due to our improved two-qubit gates with enhanced parallelism that reliably achieve record performance, even when operating many gates simultaneously. We achieved this performance using a new type of control knob that is able to turn off interactions between neighboring qubits. This greatly reduces the errors in such a multi-connected qubit system. We made further performance gains by optimizing the chip design to lower crosstalk, and by developing new control calibrations that avoid qubit defects.

We designed the circuit in a two-dimensional square grid, with each qubit connected to four other qubits. This architecture is also forward compatible for the implementation of quantum error-correction. We see our 54-qubit Sycamore processor as the first in a series of ever more powerful quantum processors.

ApplicationsThe Sycamore quantum computer is fully programmable and can run general-purpose quantum algorithms. Since achieving quantum supremacy results last spring, our team has already been working on near-term applications, including quantum physics simulation and quantum chemistry, as well as new applications in generative machine learning, among other areas.

We also now have the first widely useful quantum algorithm for computer science applications: certifiable quantum randomness. Randomness is an important resource in computer science, and quantum randomness is the gold standard, especially if the numbers can be self-checked (certified) to come from a quantum computer. Testing of this algorithm is ongoing, and in the coming months we plan to implement it in a prototype that can provide certifiable random numbers.

Whats Next?Our team has two main objectives going forward, both towards finding valuable applications in quantum computing. First, in the future we will make our supremacy-class processors available to collaborators and academic researchers, as well as companies that are interested in developing algorithms and searching for applications for todays NISQ processors. Creative researchers are the most important resource for innovation now that we have a new computational resource, we hope more researchers will enter the field motivated by trying to invent something useful.

Second, were investing in our team and technology to build a fault-tolerant quantum computer as quickly as possible. Such a device promises a number of valuable applications. For example, we can envision quantum computing helping to design new materials lightweight batteries for cars and airplanes, new catalysts that can produce fertilizer more efficiently (a process that today produces over 2% of the worlds carbon emissions), and more effective medicines. Achieving the necessary computational capabilities will still require years of hard engineering and scientific work. But we see a path clearly now, and were eager to move ahead.

AcknowledgementsWed like to thank our collaborators and contributors University of California Santa Barbara, NASA Ames Research Center, Oak Ridge National Laboratory, Forschungszentrum Jlich, and many others who helped along the way.

Today we published the results of this quantum supremacy experiment in the Nature article, Quantum Supremacy Using a Programmable Superconducting Processor. We developed a new 54-qubit processor, named Sycamore, that is comprised of fast, high-fidelity quantum logic gates, in order to perform the benchmark testing. Our machine performed the target computation in 200 seconds, and from measurements in our experiment we determined that it would take the worlds fastest supercomputer 10,000 years to produce a similar output.

Each run of a random quantum circuit on a quantum computer produces a bitstring, for example 0000101. Owing to quantum interference, some bitstrings are much more likely to occur than others when we repeat the experiment many times. However, finding the most likely bitstrings for a random quantum circuit on a classical computer becomes exponentially more difficult as the number of qubits (width) and number of gate cycles (depth) grow.

The Sycamore ProcessorThe quantum supremacy experiment was run on a fully programmable 54-qubit processor named Sycamore. Its comprised of a two-dimensional grid where each qubit is connected to four other qubits. As a consequence, the chip has enough connectivity that the qubit states quickly interact throughout the entire processor, making the overall state impossible to emulate efficiently with a classical computer.

The success of the quantum supremacy experiment was due to our improved two-qubit gates with enhanced parallelism that reliably achieve record performance, even when operating many gates simultaneously. We achieved this performance using a new type of control knob that is able to turn off interactions between neighboring qubits. This greatly reduces the errors in such a multi-connected qubit system. We made further performance gains by optimizing the chip design to lower crosstalk, and by developing new control calibrations that avoid qubit defects.

We designed the circuit in a two-dimensional square grid, with each qubit connected to four other qubits. This architecture is also forward compatible for the implementation of quantum error-correction. We see our 54-qubit Sycamore processor as the first in a series of ever more powerful quantum processors.

ApplicationsThe Sycamore quantum computer is fully programmable and can run general-purpose quantum algorithms. Since achieving quantum supremacy results last spring, our team has already been working on near-term applications, including quantum physics simulation and quantum chemistry, as well as new applications in generative machine learning, among other areas.

We also now have the first widely useful quantum algorithm for computer science applications: certifiable quantum randomness. Randomness is an important resource in computer science, and quantum randomness is the gold standard, especially if the numbers can be self-checked (certified) to come from a quantum computer. Testing of this algorithm is ongoing, and in the coming months we plan to implement it in a prototype that can provide certifiable random numbers.

Whats Next?Our team has two main objectives going forward, both towards finding valuable applications in quantum computing. First, in the future we will make our supremacy-class processors available to collaborators and academic researchers, as well as companies that are interested in developing algorithms and searching for applications for todays NISQ processors. Creative researchers are the most important resource for innovation now that we have a new computational resource, we hope more researchers will enter the field motivated by trying to invent something useful.

Second, were investing in our team and technology to build a fault-tolerant quantum computer as quickly as possible. Such a device promises a number of valuable applications. For example, we can envision quantum computing helping to design new materials lightweight batteries for cars and airplanes, new catalysts that can produce fertilizer more efficiently (a process that today produces over 2% of the worlds carbon emissions), and more effective medicines. Achieving the necessary computational capabilities will still require years of hard engineering and scientific work. But we see a path clearly now, and were eager to move ahead.

AcknowledgementsWed like to thank our collaborators and contributors University of California Santa Barbara, NASA Ames Research Center, Oak Ridge National Laboratory, Forschungszentrum Jlich, and many others who helped along the way.

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Google AI Blog: Quantum Supremacy Using a Programmable ...

Quantum computing pioneer Umesh Vazirani to give Cruickshank Lecture as part of three-day conference – EurekAlert

KINGSTON, R.I. Oct. 12, 2021 University of California, Berkeley Professor Umesh Vazirani, a pioneer in quantum computing algorithms and complexity theory, will deliver the annual University of Rhode Island Cruickshank Lecture on Monday, Oct. 18, in conjunction with the three-day Frontiers in Quantum Computing conference.

Frontiers in Quantum Computing, which celebrates the launch this semester of URIs new masters degree in quantum computing, will take place Oct. 18-20 on the Kingston Campus. More than 30 experts in the fields of quantum computing and quantum information science will deliver daily talks on such topics as the future of quantum computing, research and industry developments, and educational initiatives for the next generation of experts in the field.

This will be an impressive gathering, said Vanita Srinivasa, director of URIs Quantum Information Science program and a conference organizer. These scientists have made seminal contributions to quantum computing and quantum information science. We have speakers who are well-established in quantum information science, even before it was a major field, and we have speakers who are up and coming and are now among the top researchers in their fields.

Vazirani, the Roger A. Strauch Professor of Electrical Engineering and Computer Science at UC Berkeley and director of the Berkeley Quantum Computation Center, is considered one of the founders of the field of quantum computing. His talk will explore quantum computings impact on the foundations of quantum mechanics and the philosophy of science.

There are several different theories about how quantum mechanics can be interpreted. Advances in quantum computing will change our understanding of the foundations of quantum mechanics and maybe our overall view of the universe, said Leonard Kahn, chair of the URIDepartment of Physicswho helped organize the conference.

Vaziranis virtual talk, A Quantum Wave in Computing, will be presented to an in-person audience in room 100 of the Beaupre Center for Chemical and Forensic Sciences, 140 Flagg Road, on the Kingston campus, at 6:30 p.m. on Oct. 18. The lecture can also be viewed live with a link from the conferenceswebsite.

The conferences list of speakers includes U.S. Sen. Jack Reed, who will deliver an address at 9:45 am. on the opening day of the conference, along with experts from around the U.S. as well as Australia, Canada, Netherlands, and Denmark.

Jacob Taylor, a physicist at the National Institute of Standards and Technology, Joint Quantum Institute Fellow, and founder of the national effort overseeing implementation of the National Quantum Initiative Act, will deliver the conferences opening keynote address on Monday, Oct. 18, at 8 a.m. in the Ballroom of the Memorial Union.

Charles Tahan, assistant director for Quantum Information Science and director of the National Quantum Coordination Office in the White House Office of Science and Technology Policy (OTSP), will give the keynote address before the roundtable discussion on the future of quantum computing on Tuesday, Oct. 19, at 5:15 p.m. in the ballroom, which is sponsored by D-Wave.

The panel will include Taylor, the first assistant director for Quantum Information Science at the OSTP; Michelle Simmons, a pioneer in atomic electronics and silicon-based quantum computing and director of the Australian Research Councils Centre of Excellence for Quantum Computation and Communication Technology; Catherine McGeoch, Senior Scientist with D-Wave; and Christopher Lirakis, IBM Quantum Lead For Quantum Systems Deployment.

The panelists will provide their perspectives on the future of quantum computing from industry, government and academia, said Srinivasa. The future is uncertain, but hopeful, and there are exciting challenges along the way. Quantum computing technology has progressed from something thats been a dream to something that can actually be built.

Quantum computers have the promise of solving key problems that would take a prohibitively long time to execute on classical computers. Because of the nature of the quantum bit, as compared to the classical bit, some of those intractable calculations can be done on a quantum computer in minutes rather than thousands of years. The impact on many problems from molecular simulations to encryption of credit card data will have far-reaching consequences.

I dont think theres been a time when theres been this much publicity and press about quantum computing, said Kahn. Theres clearly a path forward but there are a lot of hurdles along the way.

With the conference celebrating URIs masters in quantum computing, education will be an important topic. Daily speakers will explore education initiatives, including developing curriculum at all levels to make the field more accessible to students. Presentations will include Chandralekha Singh, president of the American Association of Physics Teachers; Charles Robinson, IBM Quantum Computing Public Sector leader; and Robert Joynt, of the University of Wisconsin-Madison.

Other topics include implementation of quantum computing and industry developments, including talks by Christopher Savoie 92, founder and chief executive officer of Zapata Computing and a conference organizer, and Andrew King, director of Performance Research at D-Wave.

Its going to be amazing science that will be talked about at the conference, said Srinivasa, whose research focuses on quantum information processing theory for semiconductor systems. Christopher Savoie has commented that this conference is equivalent to any of the major conferences on quantum computing that hes been to.

###

Frontiers in Quantum Computing is free and open to the public. Except for the Cruickshank Lecture, all events will be held in the Memorial Union Ballroom, 50 Lower College Road, on the Kingston Campus. While events are in-person, some speakers will take part virtually. All sessions can also be viewed online. For more information or to take part, go to the conferenceswebsite.

The conference is sponsored by Zapata Computing, D-Wave, IBM Quantum, PSSC Labs, and Microway, along with URIs College of Arts and Sciences, University Libraries, Information Technology Services, the Office of the Provost, and the Department of Physics.

The Alexander M. Cruickshank Endowed Lectureship was established in 1999. It is named for Alexander M. Cruickshank, who served on the URI chemistry faculty for 30 years and was subsequently the director of the Gordon Research Conferences until his retirement in 1993. The lecture series is sponsored by the URI Department of Physics, the Gordon Research Center and URIs College of Arts and Sciences.

For more information, contact Leonard Kahn atlenkahn@uri.edu.

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Quantum computing pioneer Umesh Vazirani to give Cruickshank Lecture as part of three-day conference - EurekAlert

IONQ Stock: Why It Increased Today – Pulse 2.0

The stock price of IonQ Inc (NYSE: IONQ) increased by over 3.6% during intraday trading today. Investors are responding positively to researchers from The University of Maryland and IonQ (a leader in trapped-ion quantum computing) publishing results in the journal Nature that show a significant breakthrough in error correction technology for quantum computers.

In collaboration with scientists from Duke University and the Georgia Institute of Technology, this work demonstrated for the first time how quantum computers can overcome quantum computing errors, a key technical obstacle to large-scale use cases like financial market prediction or drug discovery.

Currently, quantum computers suffer from errors when qubits encounter environmental interference. And quantum error correction works by combining multiple qubits together to form a logical qubit that more securely stores quantum information.

But storing information by itself is not enough. Quantum algorithms also need to access and manipulate the information. And to interact with information in a logical qubit without creating more errors, the logical qubit needs to be fault-tolerant.

The study (completed at the University of Maryland, peer-reviewed, and published in the journalNature) demonstrates how trapped ion systems like IonQs can soon deploy fault-tolerant logical qubits to overcome the problem of error correction at scale. And by successfully creating the first fault-tolerant logical qubit a qubit that is resilient to a failure in any one component the team has laid the foundation for quantum computers that are both reliable and large enough for practical uses such as risk modeling or shipping route optimization.

The team had demonstrated that this could be achieved with minimal overhead, requiring only nine physical qubits to encode one logical qubit. And this will allow IonQ to apply error correction only when needed, in the amount needed, while minimizing qubit cost.

Behind the study are recently graduated UMD PhD students and current IonQ quantum engineers Laird Egan and Daiwei Zhu, IonQ cofounder Chris Monroe as well as IonQ technical advisor and Duke Professor Ken Brown. And coauthors of the paper include: UMD and Joint Quantum Institute (JQI) research scientist Marko Cetina; postdoctoral researcher Crystal Noel; graduate students Andrew Risinger and Debopriyo Biswas; Duke University graduate student Dripto M. Debroy and postdoctoral researcher Michael Newman; and Georgia Institute of Technology graduate student Muyuan Li.

This news follows on the heels of other significant technological developments from IonQ. And the company recently demonstrated the industrys first Reconfigurable Multicore Quantum Architecture (RMQA) technology, which can dynamically configure 4 chains of 16 ions into quantum computing cores.

And the company also recently debuted patent-pending evaporated glass traps: technology that lays the foundation for continual improvements to IonQs hardware and supports a significant increase in the number of ions that can be trapped in IonQs quantum computers. It recently became the first quantum computer company whose systems are available for use via all major cloud providers. IonQ also recently became the first publicly-traded, pure-play quantum computing company.

KEY QUOTES:

This is about significantly reducing the overhead in computational power that is typically required for error correction in quantum computers. If a computer spends all its time and power correcting errors, thats not a useful computer. What this paper shows is how the trapped ion approach used in IonQ systems can leapfrog others to fault tolerance by taking small, unreliable parts and turning them into a very reliable device. Competitors are likely to need orders of magnitude more qubits to achieve similar error correction results.

Peter Chapman, President and CEO of IonQ

Disclaimer: This content is intended for informational purposes. Before making any investment, you should do your own analysis.

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IONQ Stock: Why It Increased Today - Pulse 2.0

IonQ and University of Maryland Researchers Demonstrate Fault-Tolerant Error Correction, Critical for Unlocking the Full Potential of Quantum…

COLLEGE PARK, Md.--(BUSINESS WIRE)--Researchers from The University of Maryland and IonQ, Inc. (IonQ) (NYSE: IONQ), a leader in trapped-ion quantum computing, on Monday published results in the journal Nature that show a significant breakthrough in error correction technology for quantum computers. In collaboration with scientists from Duke University and the Georgia Institute of Technology, this work demonstrates for the first time how quantum computers can overcome quantum computing errors, a key technical obstacle to large-scale use cases like financial market prediction or drug discovery.

Quantum computers suffer from errors when qubits encounter environmental interference. Quantum error correction works by combining multiple qubits together to form a logical qubit that more securely stores quantum information. But storing information by itself is not enough; quantum algorithms also need to access and manipulate the information. To interact with information in a logical qubit without creating more errors, the logical qubit needs to be fault-tolerant.

The study, completed at the University of Maryland, peer-reviewed, and published in the journal Nature, demonstrates how trapped ion systems like IonQs can soon deploy fault-tolerant logical qubits to overcome the problem of error correction at scale. By successfully creating the first fault-tolerant logical qubit a qubit that is resilient to a failure in any one component the team has laid the foundation for quantum computers that are both reliable and large enough for practical uses such as risk modeling or shipping route optimization. The team demonstrated that this could be achieved with minimal overhead, requiring only nine physical qubits to encode one logical qubit. This will allow IonQ to apply error correction only when needed, in the amount needed, while minimizing qubit cost.

This is about significantly reducing the overhead in computational power that is typically required for error correction in quantum computers," said Peter Chapman, President and CEO of IonQ. "If a computer spends all its time and power correcting errors, that's not a useful computer. What this paper shows is how the trapped ion approach used in IonQ systems can leapfrog others to fault tolerance by taking small, unreliable parts and turning them into a very reliable device. Competitors are likely to need orders of magnitude more qubits to achieve similar error correction results.

Behind todays study are recently graduated UMD PhD students and current IonQ quantum engineers, Laird Egan and Daiwei Zhu, IonQ cofounder Chris Monroe as well as IonQ technical advisor and Duke Professor Ken Brown. Coauthors of the paper include: UMD and Joint Quantum Institute (JQI) research scientist Marko Cetina; postdoctoral researcher Crystal Noel; graduate students Andrew Risinger and Debopriyo Biswas; Duke University graduate student Dripto M. Debroy and postdoctoral researcher Michael Newman; and Georgia Institute of Technology graduate student Muyuan Li.

The news follows on the heels of other significant technological developments from IonQ. The company recently demonstrated the industrys first Reconfigurable Multicore Quantum Architecture (RMQA) technology, which can dynamically configure 4 chains of 16 ions into quantum computing cores. The company also recently debuted patent-pending evaporated glass traps: technology that lays the foundation for continual improvements to IonQs hardware and supports a significant increase in the number of ions that can be trapped in IonQs quantum computers. Furthermore, it recently became the first quantum computer company whose systems are available for use via all major cloud providers. Last week, IonQ also became the first publicly-traded, pure-play quantum computing company.

About IonQ

IonQ, Inc. is a leader in quantum computing, with a proven track record of innovation and deployment. IonQs next-generation quantum computer is the worlds most powerful trapped-ion quantum computer, and IonQ has defined what it believes is the best path forward to scale. IonQ is the only company with its quantum systems available through the cloud on Amazon Braket, Microsoft Azure, and Google Cloud, as well as through direct API access. IonQ was founded in 2015 by Christopher Monroe and Jungsang Kim based on 25 years of pioneering research. To learn more, visit http://www.ionq.com.

About the University of Maryland

The University of Maryland, College Park is the state's flagship university and one of the nation's preeminent public research universities. A global leader in research, entrepreneurship and innovation, the university is home to more than 40,000 students,10,000 faculty and staff, and 297 academic programs. As one of the nations top producers of Fulbright scholars, its faculty includes two Nobel laureates, three Pulitzer Prize winners and 58 members of the national academies. The institution has a $2.2 billion operating budget and secures more than $1 billion annually in research funding together with the University of Maryland, Baltimore. For more information about the University of Maryland, College Park, visit http://www.umd.edu.

Forward-Looking Statements

This press release contains certain forward-looking statements within the meaning of Section 27A of the Securities Act of 1933, as amended, and Section 21E of the Securities Exchange Act of 1934, as amended. Some of the forward-looking statements can be identified by the use of forward-looking words. Statements that are not historical in nature, including the words anticipate, expect, suggests, plan, believe, intend, estimates, targets, projects, should, could, would, may, will, forecast and other similar expressions are intended to identify forward-looking statements. These statements include those related to the Companys ability to further develop and advance its quantum computers and achieve scale; and the ability of competitors to achieve similar error correction results. Forward-looking statements are predictions, projections and other statements about future events that are based on current expectations and assumptions and, as a result, are subject to risks and uncertainties. Many factors could cause actual future events to differ materially from the forward-looking statements in this press release, including but not limited to: market adoption of quantum computing solutions and the Companys products, services and solutions; the ability of the Company to protect its intellectual property; changes in the competitive industries in which the Company operates; changes in laws and regulations affecting the Companys business; the Companys ability to implement its business plans, forecasts and other expectations, and identify and realize additional partnerships and opportunities; and the risk of downturns in the market and the technology industry including, but not limited to, as a result of the COVID-19 pandemic. The foregoing list of factors is not exhaustive. You should carefully consider the foregoing factors and the other risks and uncertainties described in the Risk Factors section of the registration statement on Form S-4 and other documents filed by the Company from time to time with the Securities and Exchange Commission. These filings identify and address other important risks and uncertainties that could cause actual events and results to differ materially from those contained in the forward-looking statements. Forward-looking statements speak only as of the date they are made. Readers are cautioned not to put undue reliance on forward-looking statements, and the Company assumes no obligation and do not intend to update or revise these forward-looking statements, whether as a result of new information, future events, or otherwise. The Company does not give any assurance that it will achieve its expectations.

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IonQ and University of Maryland Researchers Demonstrate Fault-Tolerant Error Correction, Critical for Unlocking the Full Potential of Quantum...

Discovery Fund to Seed Local Innovation Ecosystem – Maryland Today

University of Maryland President Darryll J. Pines today announced the creation of the Discovery Fund, which will support innovative companies and startups based in College Park and throughout Prince Georges County with up to $1 million a year from the university.

The first round of support is earmarked to help build a network of quantum business focused around UMD, Pines said in an address at the universitys inaugural Quantum Investment Summit. The two-day event was designed to connect investors and innovators in the growing quantum business and technology space, and drew more than 300 in-person and virtual participants from U.S. and international companies and organizations.

The university has long been a powerhouse in quantum physics research as well as a leader in designing and engineering technology based on this revolutionary branch of scienceone expected to result in quantum computers with unprecedented capabilities as well as disruptive advances in material science, digital security, health care and other fields.

UMDs growing commitment to strengthening the industrys foundation further solidifies the universitys status as the heart of the Capital of Quantum, Pines said.

This continual building on the infrastructure needed to catalyze startups and create groundbreaking products is absolutely essential if were to support and accelerate the advancement and commercialization of quantum technologies, he said. The Discovery Fund is the perfect addition to keep the momentum going around the quantum ecosystem we have been building for more than three decades.

The announcement of the new funding comes the same month that a leading quantum computing company, IonQ, went public on the New York Stock exchange with a $2 billion market valuation. The company is based in part on technology developed in UMD labs, and illustrates what the university has to gain: As IonQ works to bring quantum computing to scale, its continued close connection with UMD affords the company access to a pipeline of stellar workforce talent, Pines said today.

Another feature in UMDs expanding ecosystem is the Quantum Startup Foundry (QSF), backed by a $10 million capital investment from UMD, which will function as a business incubator to support nascent firms in the quantum technology field. The university today announced that MITRE, a not-for-profit company that works in the public interest and operates six federally funded research and development centers in areas including aviation, defense, health care, homeland security, and cybersecurity had joined as a founding QSF member.

Julie Lenzer, UMDs chief innovation officer, said offerings like the QSF and the Quantum Investment Summit help make the university central to quantum-based industry as it already is in quantum science and engineering research.

Helping to give rise to a company as successful as IonQ would be a once-in-a-lifetime thing for most schools, if that, Lenzer said. But were continuing to build on this so we can breed more success by connecting innovative quantum research and ideas with investors who want to make a difference in an area thats going to define the future.

Attendees at the investment summit included businesses ranging from giants like Lockheed Martin and IBM to new firms vying to become household names, as well as local and state officials, investors and venture capital firms.

With federal and state agencies and nations worldwide pouring many billions of dollars into quantum researchand hoping to reap the rewards of winning the race to deploy the technologyUMD, the region and the nation must strive to turn deep fundamental understanding of the science into innovation, Pines said.

Make no mistake: This is our generations space race, he said. Who will be the first to unleash the power of quantum? Im hoping its going to be us.

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Discovery Fund to Seed Local Innovation Ecosystem - Maryland Today

Quantum computing startups pull in millions as VCs rush to get ahead of the game – The Register

Venture capital firms are pouring billions into quantum computing companies, hedging bets that the technology will pay off big time some day.

Rigetti, which makes quantum hardware, announced a $1.5bn merger with Supernova Partners Acquisition Company II, a finance house focusing on strategic acquisitions. Rigetti, which was valued at $1.04bn before the deal, will now be publicly traded.

Before Rigetti's deal, quantum computer hardware and software companies raked in close to $1.02bn from venture capital investments this year, according to numbers provided to The Register by financial research firm PitchBook. That was a significant increase from $684m invested by VC firms in 2020, and $188m in 2019.

Prior to the Rigetti transaction, the biggest deal was a $450mn investment in PsiQuantum, which was valued at $3.15bn, in a round led by venture capital firm BlackRock on July 27.

Quantum computers process information differently way than classical computing. Quantum computers encode information in qubits, and store exponentially more information in the form of 1s, 0s or a superposition of both. These computers can evaluate data simultaneously, while classical computers evaluate data sequentially, simply put.

Theoretically, that makes quantum computers significantly more powerful, and enables applications like drug discovery, which are limited by the constraints of classical computers.

Rigetti and PsiQuantum are startups in a growing field of quantum computer makers that includes heavyweights IBM and Google, which are building superconducting quantum systems based on transmon qubits. D-Wave offers a quantum-annealing system based on flux bits to solve limited-sized problems, but this week said it was building a new superconducting system to solve larger problems.

Quantum computers show promise but still immature, with questions around stability, said Linley Gwennap, president of Linley Group, in a research note last month.

"Solving the error-rate problem will require substantially new approaches. If researchers can meet that challenge, quantum processors will provide an excellent complement to classical processors," Gwennap wrote.

If quantum ever works, there could be a huge market, hence the VC interest, but the technology is years away from significant revenue, Gwennap told The Register.

Deals by SPAC (special purpose acquisition companies) like Supernova Partners tend to be highly speculative, but the venture firm's due diligence on Rigetti was more around the possible rewards if quantum computers live up to their hype.

Rigetti's quantum technology is scalable, practical and manufacturable, said Supernova's chief financial officer Michael Clifton, in a press conference this week related to the deal.

"Quantum is expected to be as important as mobile and cloud have been over the last two decades," Clifton said, adding, "we were focused on large addressable markets, differentiated technologies and excellent management teams."

Rigetti's quantum computer is modular and scalable with qubit systems linked through faster interconnects. The company's introductory system in 2018 had 8 qubits, and will scale it up to 80 qubit multichip system with high-density I/O and 3D signalling. The company's roadmap includes a 1000-qubit system in 2024 that is "error mitigating," and a 4000-qubit system in 2026 with full error correction features.

Rigetti designs and makes the quantum computers chips in its own fabrication plant, which helps accelerate the delivery of chips. Amazon offers access to Rigetti's quantum hardware through AWS.

IT leaders in non-tech companies are taking quantum computing seriously, IDC said in May.

A survey by the analyst house in April revealed companies would allocate more than 19 per cent the annual IT budgets to quantum computing in 2023, growing from 7 per cent in 2021. Investments would in at quantum algorithms and systems available through the cloud to boost AI and cybersecurity.

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Quantum computing startups pull in millions as VCs rush to get ahead of the game - The Register

Columbia Research Sends Letter to Senator Chuck Schumer and Others – Columbia University

This week, Jeannette Wing, the executive vice president of research at Columbia, reached out to Senators KirstenGillibrand and Chuck Schumer and Representatives Adriano Espaillat,MondaireJones, and Jerrold Nadler toexpress the university's support of the Build Back Better bill, which provides "critical new funding to revitalize and strengthen our nations scientific research enterprise."

In the letters, she wrote that "it is particularly encouraging that the bill also identifies both urgent and emerging areas of research as funding priorities, such as climate science, biotechnology, artificial intelligence, and quantum computing. These areas of research demand our immediate attention to improve our collective health and prosperity, and to ensure our role as the worlds innovation leader."

Wing urged the delegates to support the followingprovisions and investments included in the House bill:

House Committee on Science, Space, and Technology

House Committee on Energy and Commerce

House Committee on Agriculture

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Columbia Research Sends Letter to Senator Chuck Schumer and Others - Columbia University

How science and diplomacy inform each other – SWI swissinfo.ch – swissinfo.ch

The potential of quantum computing is one of the focuses ofa summit in Genevathataimstoimprove the dialogue between diplomatsandthescientific communityto safeguard our collective welfare.Tworesearchersexplaintherewards and risks ofquantum computing.

Dorian Burkhalter

Thescientists, diplomats, captains of industry and investors gathering inGenevafor the first-ever summit of theScience and Diplomacy Anticipator (GESDA)External linkwill, among other lofty goals, discuss howpolicymakersshouldprepare forquantumcomputing, provide governance for it,and ensure thatitis accessible to all.But what are quantum computers, and whatwill they be able to do?

Quantum computersperform calculations byexploitingtheproperties ofquantummechanics, which describes thebehaviourofatoms andparticles at a subatomic scale,for example,howelectrons interact with each other.As quantum computersoperate onthe same set of rules asmolecules do,they are,for instance,much better suitedto simulate them than classical computers are.

Today, quantum computers are small and unreliable. They are not yet able to solve problems classical computers cannot.

There is still some uncertainty, but I don't see any reason to not be able to develop such a quantum computer, although it's a huge engineering challenge, says Nicolas Gisin, professor emeritus at the University of Genevaand at the Schaffhausen Institute of Technology,and an expert in quantum technologies.

Quantum computerscouldhelp solvesome of the worlds most pressing problems. They couldaccelerate thediscovery ofmaterials for longer-lasting batteries,bettersolar panels, andnew medicaltreatments.They could also break current encryptionmethods, meaning that information secure today maybecomeat risk tomorrow.

For private companies, winning the race to develop reliable and powerful quantum computers means reaping large economic rewards. For countries, it means gaining a significant national security advantage.

Gisinsaysquantum computers capable of simulating new molecules could be 5-10 years away, while more powerful quantum computers that can break encryption could become a reality in 10-20 years.

The pace at whichthesetechnologies develop will depend on the level of investments made.Large technology firms such as IBM, Microsoft, and Googleare all developing quantum computers, while the US, China,and Europeareinvestingheavilyinquantum technologies.

Anticipating the arrival ofthesetechnologies isimportant,because you play through different scenarios, and some you may like,some you may not like,says HeikeRiel, IBM Fellow at IBMResearch in Zurich.Then you can also think of what type of regulations you may need,or what type of research you need to foster.

TheSwiss governmentis a supporter oftheGESDAfoundationwhichorganisedits first summit in Geneva fromOctober 7-9.The conferencebringstogetherscientists, diplomats, andother stakeholders to discussfuturescientific developmentsandtoanticipate their impacton society.

To work well, scientists needfavourableframeworks. There is definitely a back and forth between science and diplomacy, and science and politics, because diplomacy can also advance science, Riel says.

Politicians and diplomatsare responsible forcreatingopportunities for researchers to collaborate across borders. Initiatives and funding aimed at addressingspecifictechnical problems influence the directionofresearchefforts.

The fact that Switzerland is outside of the European research framework is an absurdity for everyone because this is just going to harm both Switzerland and Europe, Gisin says. It would be really important that Europe and Switzerland understand that we will both benefit if we talk together more and collaborate more.

Since July 2021, Switzerland haslimited accessto Horizon Europe, the European Unions flagship funding program for research and innovation due to a breakdown in negotiations on regulating bilateral relations.

Many of ourproblemstodaysuch as climate change or the Covid-19 pandemicare globalin nature.Getting governments across the world to agree to work togetheronsolutions is not easy, but researcherscan help.

The research communitylikes to worktogether globally, and this collaboration has helped historically to overcome certainbarriers, Riel says, emphasising the importance of communication in this regard.

Researchers working togetheron a global scaleduring the pandemichasled to vaccines being developed atarecord-breakingspeed.During the Cold Warat theEuropean Organization for Nuclear Research (CERN) in Geneva,Sovietscientistsremained involvedin projectswhich allowedforsomecommunicationto take place.

In science, we have a common ground and it's kind of universal; the scientists in the UnitedStates, Canada, Australia,Europeand China, they all work on the same problems, they all try to solve the same technical issues, Riel says.

Scientists also have an important role to play to inform and share facts with both policymakers and the public, even if politicians cannotrely solely on scientific evidence when making decisions. The challenges of communicatingfact-based evidencehavebeen laid bare during the pandemic.

I think it's very important that we also inform the society of what we are doingthat it's not a mystery thatscares people, Riel says.

Ultimately,to successfullyaddress global challenges scientists,diplomats and politicians willhave towork together.

It's really a cooperation between the global collaboration of the scientists and the global collaboration of the diplomats to solve the problems together, Riel says.

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How science and diplomacy inform each other - SWI swissinfo.ch - swissinfo.ch

IBM and Raytheon Technologies collaborate on AI, cryptography and quantum technologies – Scientific Computing World

IBM and Raytheon Technologies have announced a collaboration to jointly develop advanced artificial intelligence (AI), cryptographic and quantum solutions for the aerospace, defence and intelligence industries, including the federal government, as part of a strategic collaboration agreement.

Artificial intelligence and quantum technologies give aerospace and government customers the ability to design systems more quickly, better secure their communications networks and improve decision-making processes. By combining IBM's breakthrough commercial research with Raytheon Technologies' own research, plus aerospace and defence expertise, the companies will be able to crack once-unsolvable challenges.

Dario Gil, senior vice president, IBM, and director of research comments: The rapid advancement of quantum computing and its exponential capabilities has spawned one of the greatest technological races in recent history one that demands unprecedented agility and speed. Our new collaboration with Raytheon Technologies will be a catalyst in advancing these state-of-the-art technologies combining their expertise in aerospace, defence and intelligence with IBM's next-generation technologies to make discovery faster, and the scope of that discovery larger than ever.

In addition to artificial intelligence and quantum, the companies will jointly research and develop advanced cryptographic technologies that lie at the heart of some of the toughest problems faced by the aerospace industry and government agencies.

Mark Russell, Raytheon Technologies chief technology officer added: Take something as fundamental as encrypted communications. As computing and quantum technologies advance, existing cybersecurity and cryptography methods are at risk of becoming vulnerable. IBM and Raytheon Technologies will now be able to collaboratively help customers maintain secure communications and defend their networks better than previously possible.

The companies are building a technical collaboration team to quickly insert IBM's commercial technologies into active aerospace, defence and intelligence programs. The same team will also identify promising technologies for jointly developing long-term system solutions by investing research dollars and talent.

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IBM and Raytheon Technologies collaborate on AI, cryptography and quantum technologies - Scientific Computing World

Common Myths About Hair Transplants

Although hair loss is a distressing condition, it's only natural to find yourself considering the idea of getting a hair transplant.

Hair transplants, otherwise known as follicular unit extraction (FUE) and follicular unit transplantation (FUT), can both be used to restore your head of hair - but you should know that there are a few myths about the procedure.

As an overview, a hair transplant involves taking hair from the back or sides of your head to cover bald patches in the front and crown of your scalp. If you opt for FUT surgery, a strip of tissue is taken from the back or sides of your head containing hair follicles. The strip is then divided into small grafts, which are transplanted into the bald patches of your scalp. As an alternative, FUE surgery involves small round punches being taken from the back or sides of your head and placed directly in the balding area.

If you're considering getting a hair transplant, here are some of the most common myths about the procedure to watch out for:

Myth 1 - New hair will go on to replace the lost hair-

The newly transplanted hairs don't immediately grow to replace your natural hair. These are both FUT and FUE methods of treatment, but they differ in the appearance that they give you. With a FUT procedure, there's a linear scar on the back or side of your head, which can be covered up with your natural hair. As opposed to this, FUE is best for those who don't want to have a linear scar because it involves small round punches being taken from the back and sides of your head where there's still healthy hair growth. In terms of appearance, you might feel like your head is still patchy following a FUT procedure. It can take between six and 18 months for the transplanted hair to grow up and cover the scar tissue caused by surgery, so you need to be patient.

Myth 2 - A hair transplant will cost a fortune-

The best place to find out about affordable hair transplants in Lahore is on the internet if you know which clinic to choose.

There are a number of hair transplant clinics in the UK, such as Crown Clinic Birmingham and Crown Clinic Manchester. While you might think that it's best to find a local clinic, be wary of fly-by-night operations. Hair transplants aren't cheap, but there are some reputable clinics that make the process affordable.

Myth 3 - Hair transplants can't be reversed-

Both FUT and FUE have a high success rate, but you need to remember that they're not permanent fixes. If you have a FUT procedure, your head of hair will look very natural. When you go into surgery for the procedure. The only way that you're going to have problems with this type of procedure. Is if you don't go through the aftercare process and use products like minoxidil, which is a topical treatment for hair loss. If you stop using these products, there's a chance that your head of hair will fall out.

As an FUE patient, you need to know that it's possible for the hair. That was harvested and transplanted to fall out eventually. There's a chance that your head of hair could fall out in the same way that it did before your procedure. So make sure you buy top-quality products like minoxidil as soon as you go through with this type of surgery.

Myth 4 - Hair transplants can be done with a topical treatment-

If you have a hair transplant using a FUT procedure, the result will look natural. It will take six to 18 months for your head of hair to grow up and cover the scar from surgery. But if you stop using minoxidil products this could take longer. The same is true for an FUE procedure. It can take a long time to get the results that you want, and without continued use of minoxidil, this might never happen.

Myth 5 - A hair transplant is going to solve all your problems-

This is where research comes into play. If you're thinking about getting a hair transplant, you need to make sure that you talk to your surgeon about the different options that are available. Some people have success with topical treatments like minoxidil, but it's possible for this not to work. A more permanent solution might be best for your circumstances, such as a FUT or FUE procedure.

You can also try PRP treatments. These have a lower success rate than FUT and FUE, but they're more affordable. You need to consider your options carefully before going for one of these treatments.

a hair transplant will cost you between £4000-£6000 in the UK.*

Myth 6 - There's a one-size-fits-all solution to hair loss-

A hair transplant is just one way of solving your hair loss problems. It might be worth trying out topical treatments like minoxidil. Before you make a decision about going through with the surgery. The best place to find out more information about these procedures is with your surgeon, who will talk you through the different options that are available to you.

Conclusion:

The biggest myth is that a hair transplant will cost you between £4000-£6000 in the UK, which isn't true. You might also hear about these myths when conducting research into this type of surgery. In order to avoid being sucked into these myths and not getting the full story. Be sure that you do your research before making a decision about this surgery. You might also want to speak with your surgeon about all of the options that are available to you.

4 Bulletproof Ways to Improve Your Immune System Naturally

With the winter months coming fast, you are probably already working hard to avoid the seasonal spread of sniffles, coughs and stomach illnesses. Short of staying indoors all winter and avoiding people altogether, what can you do to avoid the bacteria and viruses all around you? You may have already stocked up on hand sanitizer and antibacterial sprays.

Get Enough Rest

While you sleep, your body repairs and recharges itself. Think of it as taking a big breath before going underwater. If you don’t get enough air, your time under the water will be shortened. If you are not getting enough sleep, your body’s systems, including your immune response, are weakened and will be less effective, leaving you far more vulnerable to contagious viruses.

To improve your immune system naturally make it your priority to get a full night’s sleep and let your body renew itself. Avoid consuming caffeine and take up restful practices such as meditation or listening to soft music before bed.

Lower Your Stress Level

Your body responds to psychological stress by releasing the hormone cortisol. The effects of cortisol aid your brain and help it function well, but at the expense of other systems. Cortisol draws resources away from your immune system, raises your blood pressure and often results in weight gain.

The good news is that it is simple to lower your stress level. In addition to getting enough rest, moderate exercise helps your body to relax and get rid of excess cortisol. Laughter is a proven way to decrease your stress response, and massages and eating healthy are beneficial as well.

Eat to Improve Immune System

Choosing the right foods can be an effective way to improve your immune system naturally. Eating vegetables, potatoes, and carrots will give your body essential vitamins and minerals, helping to strengthen and regulate your immune system. Foods high in vitamin C, especially citrus fruits and broccoli, enable your body to fend off illness. Consuming lean protein will also maintain the levels of nutrients your body uses to combat viruses.

One powerful antioxidant food is garlic. In addition to lowering cholesterol and being a natural antibiotic, garlic aids your immune system by encouraging it to make more disease-fighting white blood cells.

Good Scents and Essential Oils

poached egg with vegetables and tomatoes on blue plate

Another way to improve your immune system naturally is through aromatherapy and essential oils. Aromatherapy is about more than perfuming the air. When you inhale the scent of essential oils, you are bringing those molecules and their helpful properties directly to your respiratory system.

Many essential oils, such as tea trees, have multiple benefits to your health. Tea tree is antifungal and antibacterial, boosts the function of the immune system, relieves the symptoms of an existing cold, and even speeds healing. Eucalyptus can also be used to prevent colds and clear nasal passages.

Essential oils are extremely powerful, and only a very small amount is needed to impact your immunity, fight illness and prevent infections from worsening. Use only pure essential oils and enjoy the benefits of better health.

Aside from Improve Your Immune System, dried fruit has a number of distinct advantages:

  • Fiber - We all need fiber in our diet for good digestive health and regularity. Fiber also benefits those who are trying to lose weight.
  • Carbohydrates - We need carbohydrates to give us energy. It is jam-packed with them. They can be eaten as a snack or pick-me-upper.
  • Vitamin C - It is an excellent source of Vitamin C, which will improve your immune system. It will also help wounds heal quicker, encourage connective tissue health, and alleviate the symptoms of health conditions, such as asthma, diabetes, and high cholesterol.
  • Antioxidants - It is loaded with antioxidants, which will among others, fight cancer and promote cardiovascular health.

7 ways to keep mosquitoes away from your baby

Mosquitoes are a familiar summer pest. Many of us try to keep them away with bug spray, citronella candles and other methods. To protect the youngest members of your family from mosquitoes - especially those less than 6 months old - follow these tips:

Cover up! Dress baby in long sleeves and socks. Check socks for holes and make sure the socks always stay on the baby's feet. To keep socks from falling off, use a little bit of glue to seal the socks at the baby's ankles.

Whose baby is this?

Mosquitoes are attracted to dark colors such as blues and purples. Choose white socks or socks with patterns that don't show up against your baby's skin.

A little olive oil goes a long way. Rubbing the baby with a few drops of olive oil can help to keep mosquitoes away from your baby. Olive oil is effective because it prevents the mosquito from latching on. Make sure that you only apply a drop or two (no more than 10% of the baby's total body surface area) and wash your hands soon after.

Eliminate Standing water

Eliminate standing water in your yard. Mosquitoes can breed anywhere that there is standing water - even a bottle cap! To make sure mosquitoes don't have the chance to reproduce near your home, take all trash and recycling to the curb before the morning of your regularly scheduled pickup day. Every week or two, empty and scrub containers like wading pools, birdbaths and pet water dishes. Change the water in decorative ponds every couple of days.

Leftover rainwater is a mosquito magnet. Keep gutters clean to prevent mosquitoes from breeding there.

Pump it up! Mosquitoes are attracted to dark colors such as blues and purples. Choose white socks or socks with patterns that don't show up against your baby's skin.

Tasty treat?

Some mosquitoes are known to eat natural body chemicals called lactic acids. This may help protect babies from getting bitten, so use a little bit of lotion on your baby's arms and legs if you can. The same thing works for adults too!

Cover up! Dress baby in long sleeves and socks. Check socks for holes and make sure the socks always stay on your baby's feet. To keep socks from falling off, use a little bit of glue to seal the socks at the baby's ankles.

Wear socks and shoes with no-see-um mesh netting in the toes and heels. These socks and shoes also have socks with patterns that don't show up against your baby's skin.

You can buy socks and shoes like this from catalogs, stores or online from platforms like sock ons

Tie socks to shoes

Avoid placing socks on baby's feet and then putting socks over the socks with shoes, because mosquitoes can bite through socks. To prevent this from happening: always wear socks with shoes, tie the socks so they stay firmly in place (the baby won't be able to pull them off), and make socks short enough so that shoes cover socks.

Avoid going outside with the baby in the evening or at dawn. These are peak mosquito hours when mosquitoes are most active. If you have to go out during these times, consider using a net tent on the baby's stroller (available from infant-products stores).

Mosquitoes cannot sting through the netting.

Baby socks work for adults, too. Keep socks with alpha-hydroxy acid in drawers to use if you get mosquito bites. (Choose socks without aloe if baby's skin is sensitive.) A small study showed that socks containing 20% alpha-hydroxy acid might be effective at preventing mosquitoes from biting.

Cover baby's stroller or carriage with mosquito netting. Make sure the netting hangs down to cover all sides and that it is loose enough that mosquitoes cannot get through. You could even place socks over the top of the netting so mosquitoes can't bite from below.

NOTE: The socks should not be touching the baby's skin.

If you have socks in your diaper bag, it's easy to apply socks quickly if an emergency arises. Carry socks with you at all times (it takes only a few seconds to put socks on), and use socks to protect yourself at any outdoor event where there is a concern about mosquitoes - picnics, sports games , fishing, etc.

 

2021 Best Insights From Quantum Computing Top Leaders Quantum Computing – Forbes

View of Cyborg hand holding Quantum computing concept with qubit and devices 3d rendering

QC Investment Today

Quantum Computing (QC) proof of concept (POC) projects are growing in Q4 2021 with commercialization pilots by 2025 and broader adoption before 2030.Accelerated digital transformation and digital reshaping from the pandemic is driving investments and early IPOs (ex. Q1 announcement by IonQ). In my daily engagements pro bono with global communities (across governments, industry, computing and research organizations, NGOs, UN agencies, innovation hubs, think tanks) of more than 60K CEOs, 30K investors , 10K innovation leaders, Im finding nearly 50% are planning pilots for QC in five years. Theres an understanding that the exponential lead provided by a breakthrough in QC warrants the early investment and learnings now since practical adoption will take years.

As a measure of progress and to stimulate collaboration/sharing in QC, the non-profit IEEE held their first Quantum Week in October 2020 and is holding their second conference IEEE Quantum Week 2021 October 18-22 2021. Ill provide a follow-up article after the conference.

Quantum Physics produces Quantum Effects from Quantum Mechanics providing Quantum Information Science that includes quantum computing, quantum communications, quantum sensing, quantum measurement, quantum safe cryptography and more. I often use QC as the general term for simplicity in this article to point to Quantum Effects-related to Quantum Information Science. Quantum Information Science is the better umbrella term.

Learn From the QC Top Leaders

In this article, I will highlight QC 2021 best insights from my chats with QC top leaders in 2021. The pro bono full video interviews can be found with the non-profits such as IEEE TEMS and ACM (see interviews series Stephen Ibaraki). IEEE is the largest non-profit electrical engineering organization and responsible for many of the global standards in use today in technology.

The QC interviewees include:

Michele Mosca: Co-founder, Institute for Quantum Computing, University of Waterloo; Founder of Quantum-Safe Canada and Quantum Industry Canada; Co-founder and CEO of the quantum-safe cybersecurity company, evolutionQ.

William Hurley, who goes by the name whurley: Innovator; Serial Entrepreneur; Founder & CEO Strangeworks, about Quantum Computing.

Scott Aaronson: David J. Bruton Centennial Professor of Computer Science at the University of Texas at Austin; recipient of ACM Prize in Computing; about theoretical computer science and quantum computing. The ACM prize is the second highest award from the ACM, which is the largest non-profit computing science organization.

Stefan Woerner: IBM Quantum Applications Research & Software Lead. Stefan is considered one of the top researchers in QC applications.

QC Top Leaders Best Pointers

Michele Mosca details quantum history and being at the founding of world leading physics and quantum research groups at University of Waterloo. We discuss the future of quantum, the probabilities of success timelines, and providing quantum risk assessment. In addition, Michele and his students have founded companies in this area thus the entrepreneurship journey is shared.

We discuss categories of quantum:

Quantum computing (QC), the focus on my January Forbes article where Google in 2019 and China in 2020 provided examples of Quantum Supremacy where problems are solved in seconds that would take thousands or billions of years on classical digital computers.

Quantum safe cryptography and designs to be safe from quantum enabled attacks. NIST (National Institute of Standards and Technology) working on QC standards. Encryption being vulnerable to quantum computing capabilities including where data can be stored and decrypted later by quantum computers.

Quantum communications where China is leading and also the UN agency ITU has programs such as Quantum Information Technology for Networks.

Quantum sensing providing ultrasensitive capabilities to detect underwater deposits and seismic events plus much more.

Willan Hurley whurley shares his experiences as a serial entrepreneur including having several startups exit within the same year. whurley then shares turning his attention to QC by authoring the book, Quantum Computing for Babies, and launching his startup Strangeworks. Strangeworks provides a platform with developer tools and systems management. In our chat, whurley states, I think if you look at IBM public roadmap, if you look at IBM Q, and Rigetti, and all of the companies and what they're doing Microsoft, Google; Google, even then announce it, they think they'll have their machine in 2029...and I think that they will actually do it before. So I predict Google will have a machine online, closer to the 2025, 2026 range...There's over 500 startups involving quantum right now today. When I started three years ago, they were like 12...And you're going to see a big inflection point driven by the government investment worldwide ... whurley talks about billions invested in France, Germany, China, USA ...you've got Norway, Finland, Russia, you've got everybody in this game now.

Scott Aaronson received the 2020 ACM Prize in Computing in April 2021 for his contributions to QC. In our chat, we talk about his work and his views on QC today and into the future. Its good to view our chat - as noted in the ACM prize citation, Aaronson helped develop the concept of quantum supremacy, which denotes the milestone that is achieved when a quantum device can solve a problem that no classical computer can solve in a reasonable amount of time. Aaronson established many of the theoretical foundations of quantum supremacy experiments. Such experiments allow scientists to give convincing evidence that quantum computers provide exponential speedups without having to first build a full fault-tolerant quantum computer. The ACM citation provides notable contributions with: Boson Sampling, Fundamental Limits of Quantum Computers, Classical Complexity Theory, his respected book on QC Quantum Computing Since Democritus and Scotts work Making Quantum Computing Accessible (ex. his popular blog.Shtetl Optimized).

Here are excerpts from my extensive chat with Stefan Woerner. The interview has been edited for clarity and brevity and I used AI to provide the transcript (which has limits). I recommend going directly to the video interview for our nuanced discussion.

Stephen Ibaraki

I ask how Stefan got into quantum computing.

Stefan Woerner

And then I started to look into how can we apply this to problems I looked into before, for example, in optimization or in finance, and it turned out that, that there are many things that can be done...quantum computing gave me a new toolbox to look at the problems that I studied already for quite a while and it opened up completely new directions. It also came with quite new challenges. But but I think it's extremely exciting for me. Now having this additional tools, additional possibilities to try to solve relevant problems and eventually have an impact with optimization or with Monte Carlo simulation and things like that.

Stephen Ibaraki

That's fascinating, your grandfather's sort of stimulating this interest in mathematics and sciences in general as well...And then in your early work, using mathematics, did you use supercomputers at that time in your optimization problems?

Stefan Woerner

We did some optimization on the cloud. And we used some cloud solvers. But these were not supercomputing. So our approach was more to try to find good formulations that are accessible by the solvers. We had, for example, writing our own simulations for supply chains that could be leveraged in an optimization setting.

Stephen Ibaraki

Quantum computing is still a mystery to a lot of people and especially to developers so there's more and more tools coming out. You have the IBM challenge to try to make it easier for the broader community to start experimenting with quantum computing. But before we delve into the tools you have and how you make it accessible for proof of concepts. Let's go back to basics, what is quantum computing?

Stefan Woerner

So quantum computing is a completely new computational paradigm where you leverage the laws of quantum mechanics. And that means if we now really go to the basics, classically, you have a bit, that's either zero or one. In quantum computing, you have the quantum bit qubit, which can be a superpositions of zero or one. And that sometimes this is explained like it's 50%, zero or 50%, one. But that's not 100% true; it's really like a superposition, it's this state in between, so you can think of it as a continuous variable, in a way a continuous value. If you have two qubits they can also be entangled. And in a way, this means that the state of two qubits can be correlated. So if you can, you can construct states that are perfectly correlated, where the state of the one qubit perfectly determines the state of the other qubit. So if the one [qubit] is zero, you know, the other one is also zero. And the other way around, if the one [qubit] is one, the other is also one. So this correlation of two particles, which are two qubits, this is something that's purely quantum mechanical. This doesn't exist in classical computing and classical electronics. And if you scale this, this means that the state space of a system of qubits scales exponentially. So that the state space to describe the system really scales extremely fast to something that's way beyond you can handle classically, that alone would not be enough. There's one more feature, let's call them interference. And you know that from sound or from water, you can have constructive and destructive interference where waves are adding up or they're cancelling out. And this is something that we leverage in quantum computing, as well. So you can have this high dimensional states, and then you can let them interfere. And that's what actually then amplifies probabilities of good solutions. Now, this also tells you one important thing, a way a quantum computer is working. And the way you program a quantum computer is completely different to how you would do this classically. Because you need to translate your problem now into something that's leveraging this interference in a way.

Stephen Ibaraki

There's this idea early on in quantum computing, where they're measuring the capabilities by the number of relatively stable, qubits, or logical qubits. And then IBM came up with this idea of quantum volume. They're saying maybe qubits is not a great way of representing the capability of a quantum computing. Can you explain IBM's concept of a quantum volume?

Stefan Woerner

Qubits that we built today, let's refer to them as physical qubits. They are noisy so they after a while they lose the state, the operations that we can can use to control their state or to modify the state are not perfect. So there's an error. And that means it's so difficult to really operate with these qubits until you really have to imagine here this is really trying to harness nature as its extreme. It's, in our case, superconducting qubits. So they are in a very cold environment and shielded from external disturbances and so on. These physical qubits, they're kind of fragile and you can have lots of qubits, but if they have very high error rates, you won't be able to use all of them. Because once you operated on all of them and entangled them, and so on, you introduce so much noise that you're not getting out anything meaningful anymore. So you really need to take into account the number of qubits, that is an important factor. But as you said, not the only one. But also the errors indicating the decoherence time. So how long the qubit keeps it state, and things like that. And now the quantum volume is a single number that's determined by some benchmarking circuit. So you run some operations on your quantum hardware, where you kind of know the result, or you can evaluate the result. And you can then say, whether this is above a certain threshold or not. And then if you can run this on a certain certain number of qubits and with a certain number of operations, and this determines the quantum volume. And so the quantum volume in a way determines how many qubits you can use with a certain number of operations, meaning that the number of operations that you run sequentially is about the number of qubits. But this is kind of benchmark. So the single number benchmark that puts on it, that takes into account the number of qubits and noise and all these factors that actually impact the power of a quantum computer. Now, this is for these physical qubits, then now looking forward, once we reach a certain size and a certain quality, then we can leverage error correction. And we can get to fault tolerant quantum computing. In here, we take many physical qubits, and we encode them as one logical qubit. So there's like an abstract and logical error correction layer on top of that. And this overhead is relatively large, so it's estimated that you need a few 100 to 1000 physical qubits to get to one logical qubit. And then this logical qubit has a significantly suppressed error. And then you can start to work with that, in this clean theoretic computational paradigm where you ignore more or less the noise from the hardware.

Stephen Ibaraki

IBM, announcing their 1 million qubit roadmap by 2030. What does that roadmap mean? I know you've got some interim results that you're targeting: 2023, 2025, etc., 2030. What are the implications of this roadmap?

Stefan Woerner

So I think the next couple of years will be would be very, very exciting for different reasons. So the roadmap that we announced that says that, until 2023, we reach a quantum chip with more than 1000 qubits and also give some specifications on the error rates that these qubits should have because as I mentioned before, qubits, just the number of qubits doesn't mean too much. So the quality needs to be improved as well, to really get a more powerful quantum computer and so we get over 100 qubits. So currently we have 65 [qubits]. Last year we released 65 that can be accessed to the cloud this year, we plan to get to 127 I think, next year 433. And then after 2023 over 1000. And, in the roadmap and also the technical details, like what leads to this improvement, what are the changes that help us to grow these chips. Now getting to 1000 qubits is kind of an inflection point. And this is because, as I mentioned before, this is about the number that you need to to build a logical qubit. So that's where you can really start to study, fault tolerant quantum computing, maybe at a small scale. But, that will be then the first time this really can be investigated in depth. And then the next step to scale to the millions; also then to not have like more and more qubits on a single chip, but also go for example, you could imagine that you combine multiple chips with 1000 qubits. And that way, get a larger quantum computer. Well, that's from the technological development, this is extremely fascinating. And I think also, this path to the 1000 qubits will be extremely interesting for applications and algorithms, researchers like myself, because right now when we run algorithms on real hardware, and also when we simulate them classically, which is very, very expensive computationally, because it scales exponentially in a number of qubits...and once we scale to 60, 100, 400, 1000 cubits, this is really where we can see that the asymptotic behavior of these heuristics, so this is really where we can start to make forecasts about how they will perform for interesting problems. And I think that this will result in us getting a way better understanding of what we can do with near term quantum computers for optimization for machine learning, for things like that.

Stephen Ibaraki

Different companies and research groups come out with different claims; there's a group out of China recently came up with a claim that they've achieved some kind of quantum supremacy that it would take a supercomputer, over 2 billion years to do this kind of quantum problem of Gaussian boson sampling. Google, made some buzz, in 2019, where they released the Sycamore system, and they indicated, quantum supremacy on this quantum problem. It's not a practical problem, but really just to illustrate that it can do something that maybe supercomputers can't do. And yet IBM looked at that and said, maybe that's not as big of a breakthrough as you're indicating, because really, we can get that done on a supercomputer just by improving our algorithms to maybe a few days. So maybe it's not quantum supremacy is. So what is supremacy, what is quantum advantage? There's these words being thrown out, and what is it real?

Stefan Woerner

So we don't use quantum quantum supremacy for multiple reasons. One, is we don't believe that quantum computers will become superior to classical computers at any point. And so a quantum computer cannot speed up everything. A quantum computer can be used as an accelerator for some tasks. So I think it will always be a combination of classical and quantum computers that work in harmony to solve some problems. So it's not like you won't write your emails with a quantum computer [you will NOT be using quantum computers to write emails], you might solve some computationally heavy quantum chemical simulations or control optimization problems with a quantum computer. And now, what do we mean by quantum advantage? That's if you can do something with the help of a quantum computer that has some practical value. So I think what you mentioned are very nice experimental demonstrations. And important steps on the development of quantum computers. What we're looking for is really a practical value that has been achieved with a quantum computer. And I think that still is a bit out in the in the future.

Stephen Ibaraki

You're an expert in quantum computing, but there's different kinds of quantum computing. And what I mean by that: trapped ion concept, topological quantum computer that Microsoft has been chasing for some time, very low temperature spin, photonic, can you get into a summary of the different categories and why IBM has chosen your particular way of doing quantum computing?

Stefan Woerner

Trapped ions, spins, photonics, and also in superconducting they're different designs, we will look into superconducting qubits, because we think that's particularly in the near term, the most promising to scale...superconducting qubits are operating in very low temperature...about 50 milli Kelvin, which is, I think, 100 or 1000 times colder than outer space. So this really like just above the absolute zero temperature. And that, that sounds very challenging. But this, dilution refrigerators that get down to these temperatures, this is something that is actually quite reliable and well understood technology. So that first sounds like a big problem. But I think that's something that has been quite well understood. And if you have that solved, or if you have the environment where you can operate them, then you can process these chips, you can come up with different designs, the superconducting qubits, for example, at a larger scale than the spins. So I think, to get these near term systems, that there might be an advantage in processing, in fabricating them. And we came up with a design that is also accessible to error correction. So here's, that's an example where the theoretical research and error correction and the people who design the devices are really like collaborated very nicely because the design of the chip has been chosen such that it's good to manufacture it, and which has then let the error correction team to come up with new error correcting codes that can be run, eventually on this hardware. So these are all pieces that fit together that make us believe that we can scale this to 1000 cubits and then if we, for example, can connect larger chips also to the to the millions.

Stephen Ibaraki

I've been in computing for such a long time. And I remember in the early days, we would flick toggle switches, and program literally in binary code; we moved to assembler then we went to higher level languages. We got to a stage where you had abstraction of the hardware through an operating system; you can write to a more generic kind of code using a much higher level language and that made it much easier. So what is the work being done in that area in quantum computing, to abstract the hardware underneath from an operating standpoint; using toolkits?

Stefan Woerner

So, we just released the development roadmap earlier this year, which, addresses this to some extent, like how the stack will grow, how levels of abstraction will be included, whether this is for, like, pre defined quantum circuits, that you don't have to build the circuit yourself. But that, you know, there's hardware, a library of pre compiled for the hardware, pre compiled circuits, and it's like an optimized instruction set. And, things like that up to actual application services. And now, in terms of the actual languages, I think we are in a very interesting situation, which is a little bit different to what you explained before, because on the one side, we are at the stage of defining the new assembler standard, which is a quantum assembly language. But at the same time, we do have the classical languages, right, we do have a Python, for example, that we can embed all of this in. So we have a render situation that we can leverage the classical existing high level languages. And in this embed these new functionalities, we can write functions, classical functions, that compile or assemble or optimize some of these quantum stuff. And that, that allows us, for example, to build work on application modules. So you, I think, you mentioned qiskit before, qiskit is our open source Python framework, to program quantum computers to define quantum circuits to simulate quantum circuits and to also send them over the cloud to the real hardware. And within qiskit, we are building application modules. And here we're looking into the moment in four different application areas, there's optimization, there's natural sciences, there's machine learning, and finance. And the optimization module has been released the middle of last year. And what this does is it, it allows you to use a classical high level language to specify your optimization problem. Because that's something that has been solved, right, this is nothing quantum computing specific. Like classical optimization, subject matter experts knows how to define a optimization problem using different languages as for example, an IBM language, to model your problem. And now what the qiskit optimization module allows us to take this classical problem, and it automatically translates it into different different representations that are then accessible to different quantum optimization algorithms. So we on the one side, we still work on the assembly level. But on the other side, we have the classical language that does all the translations for us from a high level problem down to an actual circuit. And these, these optimization modules are built in such a way that it's very easy to get started. So you can, if you are like a subject matter expert in one of these domains, you can just download these modules, they are open source, and you can get the tutorials that actually allow you to use the quantum algorithm as a black box. So the entry barrier to run your first quantum optimization program on some illustrative example, is very low, forever. This whole thing is also built in such a modular and flexible way that you can use it as a black box, but you can open the black box, you can look at every level, you can tear it apart, you can replace different pieces by your own implementation, and see whether they improve, whether they change, how do they compare. So it's built in a way that is easy to get started. But that also really, really supports cutting edge research in these areas.

Stephen Ibaraki

But ultimately, if you want to have, mass proliferation, or usage, you will have to work at this much higher abstraction level. So it's easier for people to get involved. And I guess that's the reason behind the IBM challenge, right, to get people involved. And I read last year your two biggest communities who tried it, were in the data science area, and then financial services, but you also have people like high school students trying and completing the program. Can you talk about this challenge and what you're trying to do? And, and typically, what it involves maybe it's three or four stages of things that you put people through, and you actually get quite a few actually going through the entire program. So can you give us an example what that is like?

Stefan Woerner

This challenge was a collection of problems / tasks that people could apply and try to solve. And this included problems using qiskit, to solve an optimization problem. We have different difficulty...many people really reached the highest score... If I remember correctly, some people even reached the score where there was a little bit higher than anticipated. And that the challenge was one thing, but there was also a kid summer school, ...global summer school with, if I remember correctly, around four or 5000 participants globally. So we provide these educational offers, because it's really important, as you say, for people to be able to get into how this works, but what's different, to grow also the workforce in this in this area, because there will be an increasing demand. And I think, because it is so different, because it is still new, we just figured out the tip of the iceberg of what to use a quantum computer for or how to use a quantum computer to solve problems. So I think it will be extremely important to educate more people around quantum computing, and you see universities picking that up and coming up with new quantum computing curricula, and so on. And so this is important also to really leverage the full potential of this technology.

Stephen Ibaraki

Microsoft had a blog post where they indicated that it's really not suitable right now for for problems, which have a lot of data requirements, either data and in getting data in and getting data out, it's really more for certain kind of computational problems. And where you're really taking advantage of the unique capabilities within quantum computing. And you've indicated that as well, it's not a standalone; my iPhone isn't going to have a quantum computer in it; it's going to be in combination, or in hybrid form in some way. And you're seeing that with D-Wave, which has a piece of this quantum capability with their quantum annealing, but they have these hybrid systems. That leads to this question, what kind of industries are really suitable for quantum computing? What kind of problems are really suitable for quantum computing? What are the different categories where this whole quantum phenomena is being exploited right now? Or you think we'll have some major kind of advantages going into the future?

Stefan Woerner

Let me get back to the first point you mentioned about data. Because I think that's important. I indicated at the beginning that quantum computers can solve some problems better and that's really important, not all problems. And big data problems are like, if the problem is not that the tasks you want to execute is computationally very complex, but that you want to run it on like a tremendously large data set. Then this is very likely not a quantum computing use case, because loading this large data to a quantum computer just has complexity of the size of the data. But then many of these large are many of these big data algorithms. Classical algorithms also have that complexity, like if you have a big data set and your complexity is quadratic in the data size, and this probably won't work. And that means that loading a big data set into a quantum computer. Well, and here we're talking most likely about a fault tolerant quantum computer will have the same complexity as doing a solving the problem you're interested in classically. So for some problems is just a fundamental limitation; the good example is Grover's search, which is sometimes illustrated as searching unstructured database. But the first thing you have to do is you have to load this database into a quantum computer. And when you load this, and you have to take every element, then you just stop when you found what you're looking for. So we don't load the full database to the quantum computer, but that you would have to search it. So these things can happen. I think particularly in quantum machine learning algorithms, often this fact is is not considered. And still there are some interesting theoretical results. But if you want to look into this, from an application point of view, you really need to analyze it end to end from loading the data to extracting the result. And only then you can make a statement about a potential practical quantum advantage. Now on your question in the industries, so we actually working with quite a lot of companies; I think in the IBM quantum network, we have over 130 members by now. And there's of course, the financial service sector we're working with; with JP Morgan Chase, Goldman Sachs, on things like options, pricing, the derivative pricing and credit risk analysis or risk analysis in general, also optimization, portfolio optimization, things like that. So, I think the financial service sector is an industry that has a lot of of interest in quantum computing, because it's a very compute intensive industry. And, for example, many, many things are done by a Monte Carlo simulation, where we might have some potential speed ups with quantum computing. But there's also a lot of optimization and also machine learning; if you think about credit card fraud, this is something that still causes a lot of costs for the credit card industry and if they could reduce the false positives, and they would significantly reduce costs and improve proof reputation, because no customer likes accidentally blocking of their credit card. So, this is one sector, then since quantum computing might speed up optimization problems, there eventually might be a use cases around logistics supply chain, all these things...I mean, the original idea for quantum computing as Feynman formulated, this was for simulating quantum systems...quantum chemistry, quantum physics, material science, ... and eventually use cases...life science, industry and chemical industry, this these are certainly use cases that might really have a large potential...We have a lot of activities around quantum chemistry. And how to eventually scale this to get to design new materials or to understand to how chemical reactions work to build new catalysts that allow to run some chemical reactions at ambient conditions where today we require lots of energy and so on.

Stephen Ibarakiand Stefan Woener

I ask for further POCs in the near term and Stefan provides added examples. Stefan also looks longer term. ...opens up completely new ways of doing business of doing, for example, financial product, if you have like real time risk tracking, which can also maybe even prevent different things because you can react way faster. So it can lead to a way more informed decision making in multiple businesses... I think quantum quantum computing has also the potential to solve some of the really big problems that society may face in the coming years, whether this is fertilizers for food, and so on, which can use a lot of energy these days. And so this is something where it might help and there are a couple of examples where / when nature does something extremely efficient, and humans have no clue how to reproduce that. And I think with quantum computing, once we really figured out how to build this hardware, and then also, there's a lot of open questions on the algorithms. This might give us a completely new lens to look at nature, to look at how things actually work. So I would imagine that this helps us also to really push the fundamental understanding of how the world actually works, eventually.

We explore areas: quantum cryptography, quantum encryption and decryption and Shor's algorithm, a quantum accelerator, quantum sensing, quantum communications, quantum gravimeters, 20 million qubits where Shor's algorithm becomes a real factor, and in breaking RSA encryption, quantum key distribution.

We get into a discussion about quantum inspired applications (apply the principles to solve real problems today, even though the quantum hardware isn't quite there yet. And when it's ready, it scales.) Stefan provides his insights including improvements to classical software, It's a nice term for classical algorithms. I think, in principle, it's very cool if quantum algorithm research can also inspire finding new classical algorithms. I think this can happen either by kind of de-quantizing, some quantum algorithms, as we have seen, in the last years that there is a, like a quantum algorithm that promises a certain advantage. And then people have found how to kind of mimic some of the of the core parts of this algorithm using some classical sampling techniques. And they could show similar performance. I mean, this is always a little bit disappointing if you try to show a quantum advantage with this algorithm. And then classical algorithms can beat that. But I think it's a pretty cool development. But it stays a classical algorithm...that is not to forget that it is just a classical algorithm. It doesn't give you any advantage from coming from quantum; it's a classical algorithm that has been designed by using some ideas that are coming from quantum computing, but it's based on classical computers. So it will not give you a quantum advantage because it's classical.

We get into philosophical discussions about new kinds of computing and on quantum effects including on consciousness.

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2021 Best Insights From Quantum Computing Top Leaders Quantum Computing - Forbes

What is quantum computing? Everything you need to know about the strange world of quantum computers – ZDNet

While researchers don't understand everything about the quantum world, what they do know is that quantum particles hold immense potential, in particular to hold and process large amounts of information.

Quantum computing exploits the puzzling behavior that scientists have been observing for decades in nature's smallest particles think atoms, photons or electrons. At this scale, the classical laws of physics ceases to apply, and instead we shift to quantum rules.

While researchers don't understand everything about the quantum world, what they do know is that quantum particles hold immense potential, in particular to hold and process large amounts of information. Successfully bringing those particles under control in a quantum computer could trigger an explosion of compute power that would phenomenally advance innovation in many fields that require complex calculations, like drug discovery, climate modelling, financial optimization or logistics.

As Bob Sutor, chief quantum exponent at IBM, puts it: "Quantum computing is our way of emulating nature to solve extraordinarily difficult problems and make them tractable," he tells ZDNet.

Quantum computers come in various shapes and forms, but they are all built on the same principle: they host a quantum processor where quantum particles can be isolated for engineers to manipulate.

The nature of those quantum particles, as well as the method employed to control them, varies from one quantum computing approach to another. Some methods require the processor to be cooled down to freezing temperatures, others to play with quantum particles using lasers but share the goal of finding out how to best exploit the value of quantum physics.

The systems we have been using since the 1940s in various shapes and forms laptops, smartphones, cloud servers, supercomputers are known as classical computers. Those are based on bits, a unit of information that powers every computation that happens in the device.

In a classical computer, each bit can take on either a value of one or zero to represent and transmit the information that is used to carry out computations. Using bits, developers can write programs, which are sets of instructions that are read and executed by the computer.

Classical computers have been indispensable tools in the past few decades, but the inflexibility of bits is limiting. As an analogy, if tasked with looking for a needle in a haystack, a classical computer would have to be programmed to look through every single piece of hay straw until it reached the needle.

There are still many large problems, therefore, that classical devices can't solve. "There are calculations that could be done on a classical system, but they might take millions of years or use more computer memory that exists in total on Earth," says Sutor. "These problems are intractable today."

At the heart of any quantum computer are qubits, also known as quantum bits, and which can loosely be compared to the bits that process information in classical computers.

Qubits, however, have very different properties to bits, because they are made of the quantum particles found in nature those same particles that have been obsessing scientists for many years.

One of the properties of quantum particles that is most useful for quantum computing is known as superposition, which allows quantum particles to exist in several states at the same time. The best way to imagine superposition is to compare it to tossing a coin: instead of being heads or tails, quantum particles are the coin while it is still spinning.

By controlling quantum particles, researchers can load them with data to create qubits and thanks to superposition, a single qubit doesn't have to be either a one or a zero, but can be both at the same time. In other words, while a classical bit can only be heads or tails, a qubit can be, at once, heads and tails.

This means that, when asked to solve a problem, a quantum computer can use qubits to run several calculations at once to find an answer, exploring many different avenues in parallel.

So in the needle-in-a-haystack scenario about, unlike a classical machine, a quantum computer could in principle browse through all hay straws at the same time, finding the needle in a matter of seconds rather than looking for years even centuries before it found what it was searching for.

What's more: qubits can be physically linked together thanks to another quantum property called entanglement, meaning that with every qubit that is added to a system, the device's capabilities increase exponentially where adding more bits only generates linear improvement.

Every time we use another qubit in a quantum computer, we double the amount of information and processing ability available for solving problems. So by the time we get to 275 qubits, we can compute with more pieces of information than there are atoms in the observable universe. And the compression of computing time that this could generate could have big implications in many use cases.

Quantum computers are all built on the same principle: they host a quantum processor where quantum particles can be isolated for engineers to manipulate.

"There are a number of cases where time is money. Being able to do things more quickly will have a material impact in business," Scott Buchholz, managing director at Deloitte Consulting, tells ZDNet.

The gains in time that researchers are anticipating as a result of quantum computing are not of the order of hours or even days. We're rather talking about potentially being capable of calculating, in just a few minutes, the answer to problems that today's most powerful supercomputers couldn't resolve in thousands of years, ranging from modelling hurricanes all the way to cracking the cryptography keys protecting the most sensitive government secrets.

And businesses have a lot to gain, too. According to recent research by Boston Consulting Group (BCG),the advances that quantum computing will enable could create value of up to $850 billion in the next 15 to 30 years, $5 to $10 billion of which will be generated in the next five years if key vendors deliver on the technology as they have promised.

Programmers write problems in the form of algorithms for classical computers to resolve and similarly, quantum computers will carry out calculations based on quantum algorithms. Researchers have already identified that some quantum algorithms would be particularly suited to the enhanced capabilities of quantum computers.

For example, quantum systems could tackle optimization algorithms, which help identify the best solution among many feasible options, and could be applied in a wide range of scenarios ranging from supply chain administration to traffic management. ExxonMobil and IBM, for instance, are working together to find quantum algorithmsthat could one day manage the 50,000 merchant ships crossing the oceans each day to deliver goods, to reduce the distance and time traveled by fleets.

Quantum simulation algorithms are also expected to deliver unprecedented results, as qubits enable researchers to handle the simulation and prediction of complex interactions between molecules in larger systems, which could lead to faster breakthroughs in fields like materials science and drug discovery.

With quantum computers capable of handling and processing much larger datasets,AI and machine-learning applications are set to benefit hugely, with faster training times and more capable algorithms. And researchers have also demonstrated that quantum algorithmshave the potential to crack traditional cryptography keys, which for now are too mathematically difficult for classical computers to break.

To create qubits, which are the building blocks of quantum computers, scientists have to find and manipulate the smallest particles of nature tiny parts of the universe that can be found thanks to different mediums. This is why there are currently many types of quantum processors being developed by a range of companies.

One of the most advanced approaches consists of using superconducting qubits, which are made of electrons, and come in the form of the familiar chandelier-like quantum computers. Both IBM and Google have developed superconducting processors.

Another approach that is gaining momentum is trapped ions, which Honeywell and IonQ are leading the way on, and in which qubits are housed in arrays of ions that are trapped in electric fields and then controlled with lasers.

Major companies like Xanadu and PsiQuantum, for their part, are investing in yet another method that relies on quantum particles of light, called photons, to encode data and create qubits. Qubits can also be created out of silicon spin qubits which Intel is focusing on but also cold atoms or even diamonds.

Quantum annealing, an approach that was chosen by D-Wave, is a different category of computing altogether. It doesn't rely on the same paradigm as other quantum processors, known as the gate model. Quantum annealing processors are much easier to control and operate, which is why D-Wave has already developed devices that can manipulate thousands of qubits, where virtually every other quantum hardware company is working with about 100 qubits or less. On the other hand, the annealing approach is only suitable for a specific set of optimization problems, which limits its capabilities.

Both IBM and Google have developed superconducting processors.

Right now, with a mere 100 qubits being the state of the art, there is very little that can actually be done with quantum computers. For qubits to start carrying out meaningful calculations, they will have to be counted in the thousands, and even millions.

"While there is a tremendous amount of promise and excitement about what quantum computers can do one day, I think what they can do today is relatively underwhelming," says Buchholz.

Increasing the qubit count in gate-model processors, however, is incredibly challenging. This is because keeping the particles that make up qubits in their quantum state is difficult a little bit like trying to keep a coin spinning without falling on one side or the other, except much harder.

Keeping qubits spinning requires isolating them from any environmental disturbance that might cause them to lose their quantum state. Google and IBM, for example, do this by placing their superconducting processors in temperatures that are colder than outer space, which in turn require sophisticated cryogenic technologies that are currently near-impossible to scale up.

In addition, the instability of qubits means that they are unreliable, and still likely to cause computation errors. This hasgiven rise to a branch of quantum computing dedicated to developing error-correction methods.

Although research is advancing at pace, therefore, quantum computers are for now stuck in what is known as the NISQ era: noisy, intermediate-scale quantum computing but the end-goal is to build a fault-tolerant, universal quantum computer.

As Buchholz explains, it is hard to tell when this is likely to happen. "I would guess we are a handful of years from production use cases, but the real challenge is that this is a little like trying to predict research breakthroughs," he says. "It's hard to put a timeline on genius."

In 2019, Googleclaimed that its 54-qubit superconducting processor called Sycamore had achieved quantum supremacy the point at which a quantum computer can solve a computational task that is impossible to run on a classical device in any realistic amount of time.

Google said that Sycamore has calculated, in only 200 seconds, the answer to a problem that would have taken the world's biggest supercomputers 10,000 years to complete.

More recently,researchers from the University of Science and Technology of China claimed a similar breakthrough, saying that their quantum processor had taken 200 seconds to achieve a task that would have taken 600 million years to complete with classical devices.

This is far from saying that either of those quantum computers are now capable of outstripping any classical computer at any task. In both cases, the devices were programmed to run very specific problems, with little usefulness aside from proving that they could compute the task significantly faster than classical systems.

Without a higher qubit count and better error correction, proving quantum supremacy for useful problems is still some way off.

Organizations that are investing in quantum resources see this as the preparation stage: their scientists are doing the groundwork to be ready for the day that a universal and fault-tolerant quantum computer is ready.

In practice, this means that they are trying to discover the quantum algorithms that are most likely to show an advantage over classical algorithms once they can be run on large-scale quantum systems. To do so, researchers typically try to prove that quantum algorithms perform comparably to classical ones on very small use cases, and theorize that as quantum hardware improves, and the size of the problem can be grown, the quantum approach will inevitably show some significant speed-ups.

For example, scientists at Japanese steel manufacturer Nippon Steelrecently came up with a quantum optimization algorithm that could compete against its classical counterpartfor a small problem that was run on a 10-qubit quantum computer. In principle, this means that the same algorithm equipped with thousands or millions of error-corrected qubits could eventually optimize the company's entire supply chain, complete with the management of dozens of raw materials, processes and tight deadlines, generating huge cost savings.

The work that quantum scientists are carrying out for businesses is, therefore, highly experimental, and so far there are fewer than 100 quantum algorithms that have been shown to compete against their classical equivalents which only points to how emergent the field still is.

With most use cases requiring a fully error-corrected quantum computer, just who will deliver one first is the question on everyone's lips in the quantum industry, and it is impossible to know the exact answer.

All quantum hardware companies are keen to stress that their approach will be the first one to crack the quantum revolution, making it even harder to discern noise from reality. "The challenge at the moment is that it's like looking at a group of toddlers in a playground and trying to figure out which one of them is going to win the Nobel Prize," says Buchholz.

"I have seen the smartest people in the field say they're not really sure which one of these is the right answer. There are more than half a dozen different competing technologies and it's still not clear which one will wind up being the best, or if there will be a best one," he continues.

In general, experts agree that the technology will not reach its full potential until after 2030. The next five years, however, may start bringing some early use cases as error correction improves and qubit counts start reaching numbers that allow for small problems to be programmed.

IBM is one of the rare companies thathas committed to a specific quantum roadmap, which defines the ultimate objective of realizing a million-qubit quantum computer. In the nearer term, Big Blue anticipates that it will release a 1,121-qubit system in 2023, which might mark the start of the first experimentations with real-world use cases.

In general, experts agree that quantum computers will not reach their full potential until after 2030.

Developing quantum hardware is a huge part of the challenge, and arguably the most significant bottleneck in the ecosystem. But even a universal fault-tolerant quantum computer would be of little use without the matching quantum software.

"Of course, none of these online facilities are much use without knowing how to 'speak' quantum," Andrew Fearnside, senior associate specializing in quantum technologies at intellectual property firm Mewburn Ellis, tells ZDNet.

Creating quantum algorithms is not as easy as taking a classical algorithm and adapting it to the quantum world. Quantum computing, rather, requires a brand-new programming paradigm that can only be run on a brand-new software stack.

Of course, some hardware providers also develop software tools, the most established of which is IBM's open-source quantum software development kit Qiskit. But on top of that, the quantum ecosystem is expanding to include companies dedicated exclusively to creating quantum software. Familiar names include Zapata, QC Ware or 1QBit, which all specialize in providing businesses with the tools to understand the language of quantum.

And increasingly, promising partnerships are forming to bring together different parts of the ecosystem. For example, therecent alliance between Honeywell, which is building trapped ions quantum computers, and quantum software company Cambridge Quantum Computing (CQC), has got analysts predicting that a new player could be taking a lead in the quantum race.

The complexity of building a quantum computer think ultra-high vacuum chambers, cryogenic control systems and other exotic quantum instruments means that the vast majority of quantum systems are currently firmly sitting in lab environments, rather than being sent out to customers' data centers.

To let users access the devices to start running their experiments, therefore, quantum companies have launched commercial quantum computing cloud services, making the technology accessible to a wider range of customers.

The four largest providers of public cloud computing services currently offer access to quantum computers on their platform. IBM and Google have both put their own quantum processors on the cloud, whileMicrosoft's Azure QuantumandAWS's Braketservice let customers access computers from third-party quantum hardware providers.

The jury remains out on which technology will win the race, if any at all, but one thing is for certain: the quantum computing industry is developing fast, and investors are generously funding the ecosystem. Equity investments in quantum computing nearly tripled in 2020, and according to BCG, they are set to rise even more in 2021 to reach $800 million.

Government investment is even more significant: the US has unlocked $1.2 billion for quantum information science over the next five years, while the EU announced a 1 billion ($1.20 billion) quantum flagship. The UKalso recently reached the 1 billion ($1.37 billion) budget milestonefor quantum technologies, and while official numbers are not known in China,the government has made no secret of its desire to aggressively compete in the quantum race.

This has caused the quantum ecosystem to flourish over the past years, with new startups increasing from a handful in 2013 to nearly 200 in 2020. The appeal of quantum computing is also increasing among potential customers: according to analysis firm Gartner,while only 1% of companies were budgeting for quantum in 2018, 20% are expected to do so by 2023.

Although not all businesses need to be preparing themselves to keep up with quantum-ready competitors, there are some industries where quantum algorithms are expected to generate huge value, and where leading companies are already getting ready.

Goldman Sachs and JP Morgan are two examples of financial behemoths investing in quantum computing. That's because in banking,quantum optimization algorithms could give a boost to portfolio optimization, by better picking which stocks to buy and sell for maximum return.

In pharmaceuticals, where the drug discovery process is on average a $2 billion, 10-year-long deal that largely relies on trial and error, quantum simulation algorithms are also expected to make waves. This is also the case in materials science: companies like OTI Lumionics, for example,are exploring the use of quantum computers to design more efficient OLED displays.

Leading automotive companies including Volkswagen and BMW are also keeping a close eye on the technology, which could impact the sector in various ways, ranging from designing more efficient batteries to optimizing the supply chain, through to better management of traffic and mobility. Volkswagen, for example,pioneered the use of a quantum algorithm that optimized bus routes in real time by dodging traffic bottlenecks.

As the technology matures, however, it is unlikely that quantum computing will be limited to a select few. Rather, analysts anticipate that virtually all industries have the potential to benefit from the computational speedup that qubits will unlock.

There are some industries where quantum algorithms are expected to generate huge value, and where leading companies are already getting ready.

Quantum computers are expected to be phenomenal at solving a certain class of problems, but that doesn't mean that they will be a better tool than classical computers for every single application. Particularly, quantum systems aren't a good fit for fundamental computations like arithmetic, or for executing commands.

"Quantum computers are great constraint optimizers, but that's not what you need to run Microsoft Excel or Office," says Buchholz. "That's what classical technology is for: for doing lots of maths, calculations and sequential operations."

In other words, there will always be a place for the way that we compute today. It is unlikely, for example, that you will be streaming a Netflix series on a quantum computer anytime soon. Rather, the two technologies will be used in conjunction, with quantum computers being called for only where they can dramatically accelerate a specific calculation.

Buchholz predicts that, as classical and quantum computing start working alongside each other, access will look like a configuration option. Data scientists currently have a choice of using CPUs or GPUs when running their workloads, and it might be that quantum processing units (QPUs) join the list at some point. It will be up to researchers to decide which configuration to choose, based on the nature of their computation.

Although the precise way that users will access quantum computing in the future remains to be defined, one thing is certain: they are unlikely to be required to understand the fundamental laws of quantum computing in order to use the technology.

"People get confused because the way we lead into quantum computing is by talking about technical details," says Buchholz. "But you don't need to understand how your cellphone works to use it.

"People sometimes forget that when you log into a server somewhere, you have no idea what physical location the server is in or even if it exists physically at all anymore. The important question really becomes what it is going to look like to access it."

And as fascinating as qubits, superposition, entanglement and other quantum phenomena might be, for most of us this will come as welcome news.

Read more:
What is quantum computing? Everything you need to know about the strange world of quantum computers - ZDNet

AI, quantum computing and other technologies poised to transform healthcare – Healthcare Finance News

Photo: Al David Sacks/Getty Images

The COVID-19 pandemic has created numerous challenges in healthcare, but challenges can sometimes breed innovation. Technological innovation in particular is poised to change the way care is delivered, driving efficiency in the process. Efficiency will be key as hospitals and health systems look to recover from the initial, devastating wave of the pandemic.

Ryan Hodgin, chief technology officer for IBM Global Healthcare, and Kate Huey, partner at IBM Healthcare, will speak about some of these technological innovations in their digital HIMSS21 session, "Innovation Driven Resiliency: Redefining What's Possible."

The technology in question can encompass telehealth, artificial intelligence, automation, blockchain, chatbots, apps and other elements that have become mainstays of healthcare during the course of the pandemic.

In a way, science fiction is becoming science fact: Technologies that were once in the experimental phase are now coming to life and driving innovation, particularly quantum computing. The power of quantum computing has the potential to transform healthcare just by sheer force of its impressive computational power.

One of the big factors accelerating technological innovation is the healthcare workforce, which has been placed under enormous stress over the past 18 months, with many doctors and clinicians reporting burnout or feelings of being overwhelmed. These technologies promise to reduce the burden being felt by providers.

Importantly, they also promise to more actively engage healthcare consumers, who increasingly expect healthcare to be as user-friendly and experience driven as their favorite apps or online shopping portals.

Hodgin and Huey will speak more on the topic when their session debuts on Tuesday, August 10, from 11:45 a.m. - 12:15 p.m.

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AI, quantum computing and other technologies poised to transform healthcare - Healthcare Finance News