Prophecy Market Insights Quantum Computing market research report provides a comprehensive, 360-degree analysis of the targeted market which helps stakeholders to identify the opportunities as well as challenges during COVID-19 pandemic across the globe.

Quantum Computing Devices Market reports provide in-depth analysis of Top Players, Geography, End users, Applications, Competitor analysis, Revenue, Financial Analysis, Market Share, COVID-19 Analysis, Trends and Forecast 2020-2029. It incorporates market evolution study, involving the current scenario, growth rate, and capacity inflation prospects, based on Porters Five Forces and DROT analyses.

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An executive summary provides the markets definition, application, overview, classifications, product specifications, manufacturing processes; raw materials, and cost structures.

Market Dynamics offers drivers, restraints, challenges, trends, and opportunities of the Quantum Computing market

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Segment Level Analysis in terms of types, product, geography, demography, etc. along with market size forecast

Segmentation Overview:

The Quantum Computing research study comprises 100+ market data Tables, Graphs & Figures, Pie Chat to understand detailed analysis of the market. The predictions estimated in the market report have been resulted in using proven research techniques, methodologies, and assumptions. This Quantum Computing market report states the market overview, historical data along with size, growth, share, demand, and revenue of the global industry.

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Regional and Country- level Analysis different geographical areas are studied deeply and an economical scenario has been offered to support new entrants, leading market players, and investors to regulate emerging economies. The top producers and consumers focus on production, product capacity, value, consumption, growth opportunity, and market share in these key regions, covering

The comprehensive list of Key Market Players along with their market overview, product protocol, key highlights, key financial issues, SWOT analysis, and business strategies. The report dedicatedly offers helpful solutions for players to increase their clients on a global scale and expand their favour significantly over the forecast period. The report also serves strategic decision-making solutions for the clients.

Competitive landscape Analysis provides mergers and acquisitions, collaborations along with new product launches, heat map analysis, and market presence and specificity analysis.

Quantum ComputingMarket Key Players:

Wave Systems Corp, 1QB Information Technologies Inc, QC Ware, Corp, Google Inc, QxBranch LLC, Microsoft Corporation, International Business Machines Corporation, Huawei Technologies Co., Ltd, ID Quantique SA, and Atos SE.

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Quantum Computing Market: In-Depth Market Research and Trends Analysis till 2030 - Cole of Duty

By making use of the 'spooky' laws behind quantum entanglement, physicists think have found a way to make information leap between a pair of electrons separated by distance.

Teleporting fundamental states between photonsmassless particles of light is quickly becoming old news, a trick we are still learning to exploit in computing and encrypted communications technology.

But what the latest research has achieved is quantum teleportation between particles of matter electrons something that could help connect quantum computing with the more traditional electronic kind.

"We provide evidence for 'entanglement swapping,' in which we create entanglement between two electrons even though the particles never interact, and 'quantum gate teleportation,' a potentially useful technique for quantum computing using teleportation," says physicist John Nichol from the University of Rochester in New York.

"Our work shows that this can be done even without photons."

Entanglement is physics jargon for what seems like a pretty straightforward concept.

If you buy a pair of shoes from a shop and leave one behind, you'll automatically know which foot it belongs to the moment you get home. The shoes are in a manner of speaking entangled.

If the shopkeeper randomly pulls out its matching partner when you return, you'll think they either remembered your sale, made a lucky guess, or were perhaps a little 'spooky' in their prediction.

The real weirdness arises when we imagine your lonely shoe as being both left and right at the same time, at least until you look at it. At that very moment, the shoe's partner back at the shop also snaps into shape, as if your sneaky peek teleported across that distance.

It's a kind of serendipitous exchange that Einstein felt was a little too spooky for comfort. Nearly a century after physicists raised the possibility, we now know teleportation between entangled particles is how the Universe works on a fundamental level.

While it's not exactly a Star Trek-type teleportation that could beam whole objects across space, the mathematics describing this information jump are mighty useful in carrying out special kinds of calculations in computing.

Typical computer logic is made up of a binary language of bits, labelled either 1s and 0s. Quantum computing is built with qubits that can occupy both states at once providing far greater possibilities that classical technology can't touch.

The problem is the Universe is like a big jumble of shoes, all threatening to turn your delicate game of 'guess which foot' into a nightmare gamble the moment any qubit interacts with its environment.

Manipulating photons to transmit their entangled states is made easier thanks to the fact they can be quickly separated at light speed over huge distances through a vacuum or down an optical fibre.

But separating entangled masses such as pairs of electrons is more of a challenge, given their clunky interactions as they bounce along are almost certain to ruin their mathematically pure quantum state.

It's a challenge well worth the effort, though.

"Individual electrons are promising qubits because they interact very easily with each other, and individual electron qubits in semiconductors are also scalable," saysNichol.

"Reliably creating long-distance interactions between electrons is essential for quantum computing."

To achieve it, the team of physicists and engineers took advantage of some strange fine print in the laws that govern the ways the fundamental particles making up atoms and molecules hold their place.

Any two electrons that share the same quantum spin state can't occupy the same spot in space. But there is a bit of a loophole that says nearby electrons can swap their spins, almost as if your feet could swap shoes if you bring them close enough.

The researchers had previously shownthat this exchange can be manipulated without needing to move the electrons at all, presenting a potential method for teleportation.

This latest advance helps bring the process closer to technological reality, overcoming hurdles that would connect quantum weirdness with existing computing technology.

"We provide evidence for 'entanglement swapping,' in which we create entanglement between two electrons even though the particles never interact, and 'quantum gate teleportation,' a potentially useful technique for quantum computing using teleportation," says Nichol.

"Our work shows that this can be done even without photons."

Of course, we're still some way off replacing photons with electrons for this kind of quantum information transfer. The researchers haven't gone as far as measuring the states of electrons themselves, meaning there could still be all kinds of interference to iron out.

But having strong evidence of the possibility of teleportation between electrons is an encouraging sign of the possibilities open to future engineers.

This research was published in Nature Communications.

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Physicists Just Quantum Teleported Information Between Particles of Matter - ScienceAlert

AUTOMATION

Amazon Shakes Up the Race for Self-Drivingand Ride-HailingAarian Marshal | WiredUber CEO Dara Khosrowshahi says his company wants to be the Amazon for transportation. Friday, Amazon made clear that it intends to be the Amazon for transportation. The ecommerce giant said it hadagreed to acquireBay Area-based autonomous vehicle company Zoox, a dealreportedly worth more than $1 billion.

Wrongfully Accused by an AlgorithmKashmir Hill | The New York TimesMr. Williams knew that he had not committed the crime in question. What he could not have known, as he sat in the interrogation room, is that his case may be the first known account of an American being wrongfully arrested based on a flawed match from a facial recognition algorithm, according to experts on technology and the law.

Meet Silq: The First Intuitive Programming Language for Quantum ComputersLuke Dormehl | Digital TrendsThe creation of the C programming language was a massive milestone for classical computing. It was easy, intuitive, and helped open up computer programming to an entirely new audience. Now, nearly 50 years after C was created, computer scientists have reached a similar milestone: A new programming language that brings the same level of coding simplicity to quantum computing.

How Green Sand Could Capture Billions of Tons of Carbon DioxideJames Temple | MIT Technology ReviewThis process, along with other forms of whats known as enhanced mineral weathering, could potentially store hundreds of trillions of tons of carbon dioxide, according toa National Academies report last year. Thats far more carbon dioxide than humans have pumped out since the start of the Industrial Revolution.

Scientists Made a List of Every Place Aliens Could Be HidingGeorge Dvorsky | GizmodoTheExotica Catalog further signifies the ongoing shift away from traditional SETI strategies, in which scientists search for familiar alien signatures (such as radio emissions), and the shift toward Dysonian SETI, in which scientists look for extraterrestrial technosignatures, that is, signs of alien technology: stuff like Dyson shells (a star surrounded by solar panels), industrial waste, gigantic space habitats, beacons, and things we cant even imagine.

The Rocket Motor of the Future Breathes Air Like a Jet EngineDaniel Oberhaus | WiredWhile a conventional rocket engine must carry giant tanks of fuel and oxidizer on its journey to space, an air-breathing rocket motor pulls most of its oxidizer directly from the atmosphere. This means that an air-breathing rocket can lift more stuff with less propellant and drastically lower the cost of space accessat least in theory.

$100 Billion Universal Fiber Plan Proposed by Democrats in CongressJon Brodkin | Ars Technica[Electronic Frontier Foundation Senior Legislative Counsel Ernesto Falcon] argues that a plan like Clyburns is needed for the US to deploy fiber throughout the country within a few years instead of decades. Such an ambitious program would have the United States match Chinas efforts to build universal fiber with the US completing its transition just a few short years after China, Falcon wrote. Without this law, the transition would take decades.

Does Dark Matter Exist?Ramin Skibba | Aeonover the past half century, no one has ever directly detected a single particle of dark matter. Over and over again, dark matter has resisted being pinned down, like a fleeting shadow in the woods. And as long as its not found, its still possible that there is no dark matter at all. An alternative remains: instead of huge amounts of hidden matter, some mysterious aspect of gravity could be warping the cosmos instead.

Image credit: twk tt /Unsplash

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This Week's Awesome Tech Stories From Around the Web (Through June 27) - Singularity Hub

25 June 2020

In a critical step toward creating a global quantum communications network, researchers have generated and detected quantum entanglement onboard a CubeSat nanosatellite weighing less than 2.6 kg and orbiting the Earth.

The University of Strathclyde is involved in an international team which has demonstrated that their miniaturised source of quantum entanglement can operate successfully in space aboard a low-resource, cost-effective CubeSat that is smaller than a shoebox. CubeSats are a standard type of nanosatellite made of multiples of 10 cm 10 cm 10 cm cubic units.

The quantum mechanical phenomenon known as entanglement is essential to many quantum communications applications. However, creating a global network for entanglement distribution is not possible with optical fibers because of the optical losses that occur over long distances. Equipping small, standardised satellites in space with quantum instrumentation is one way to tackle this challenge in a cost-effective manner.

The research, led by the National University of Singapore, has been published in the journal Optica.

Dr Daniel Oi, a Senior Lecturer in Strathclydes Department of Physics, is the Universitys lead on the research. He said: This research has tested next generation quantum communication technologies for use in space. With the results confirmed, its success bodes well for forthcoming missions, for which we are developing the next enhanced version of these instruments.

As a first step, the researchers needed to demonstrate that a miniaturised photon source for quantum entanglement could stay intact through the stresses of launch and operate successfully in the harsh environment of space within a satellite that can provide minimal power. To accomplish this, they exhaustively examined every component of the photon-pair source used to generate quantum entanglement to see if it could be made smaller or more rugged.

The new miniaturised photon-pair source consists of a blue laser diode that shines on nonlinear crystals to create pairs of photons. Achieving high-quality entanglement required a complete redesign of the mounts that align the nonlinear crystals with high precision and stability.

The researchers qualified their new instrument for space by testing its ability to withstand the vibration and thermal changes experienced during a rocket launch and in-space operation. The photon-pair source maintained very high-quality entanglement throughout the testing and crystal alignment was preserved, even after repeated temperature cycling from -10 C to 40 C.

The researchers incorporated their new instrument into SpooQy-1, a CubeSat that was deployed into orbit from the International Space Station on 17 June 2019. The instrument successfully generated entangled photon-pairs over temperatures from 16 C to 21.5 C.

The researchers are now working with RAL Space in the UK to design and build a quantum nanosatellite similar to SpooQy-1 with the capabilities needed to beam entangled photons from space to a ground receiver. This is slated for demonstration aboard a 2022 mission. They are also collaborating with other teams to improve the ability of CubeSats to support quantum networks.

Strathclyde is the only academic institution that has been a partner in all four EPSRC funded Quantum Technology Hubs in both phases of funding. The Hubs are in Sensing and Timing, Quantum Enhanced Imaging, Quantum Computing and Simulation and Quantum Communications Technologies. Dr Oi is Strathclydes lead on a forthcoming CubeSat mission being developed by the Quantum Communications Technologies Hub.

Dr Oi is also Chief Scientific Officer with Craft Prospect, a space engineering practice that delivers mission-enabling products and develops novel mission applications for small space missions. The company is based in the Tontine Building in the Glasgow City Innovation District, which is transforming the way academia, business and industry collaborate to bring competitive advantage to Scotland.

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Quantum entanglement demonstrated on orbiting CubeSat - University of Strathclyde

For the widest possible and mobile Internet coverage, wireless communications are essential. But due to the open nature of wireless transmissions, information security is a unique issue of challenge. The widely deployed methods for information security are based on digital encryption, which in turn requires two or more legitimate parties to share a secret key.

The distribution of a secrecy key via zero-distance physical contact is inconvenient in general and impossible in situations where too little time is available. The conventional solution to this challenge is to use the public-key infrastructure, or PKI, for secret key distribution. Yet, PKI is based on computational hardness of factoring, for example, which is known to be increasingly threatened by quantum computing. Some predictions suggest that such a threat could become a reality within 15 years.

In order to provide Internet coverage for every possible spot on the planet, such as remote islands and mountains, a low-orbiting satellite communication network is rapidly being developed. A satellite can transmit or receive streams of digital information to or from terrestrial stations. But the geographical exposure of these streams is large and easily prone to eavesdropping. For applications such as satellite communications, how can we guarantee information security even if quantum computers become readily available in the near future?

Yingbo Huas Lab of Signals, Systems and Networks in the Department of Electrical and Computer Engineering, which has been supported in part by Army, has aimed to develop reliable and secure transmission, or RESET, schemes for future wireless networks. RESET guarantees that the secret information is not only received reliably by legitimate receiver but also secure from eavesdropper with any channel superiority.

In particular, Huas Lab has developed a physical layer encryption method that could be immune to the threat of quantum computing. They are actively engaged in further research of this and other related methods.

For the physical layer encryption proposed by Huas lab, only partial information is extracted from randomized matrices such as the principal singular vector of each matrix modulated by secret physical feature approximately shared by legitimate parties. The principal singular vector of a matrix is not a reversible function of the matrix. This seems to suggest that a quantum computer is unable to perform a task that is rather easy on a classical computer. If this is true, then the physical layer encryption should be immune from attacks via quantum computing. Unlike the number theory based encryption methods which are vulnerable to quantum attacks, Huas physical layer encryption is based on continuous encryption functions that are still yet to be developed.

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Better encryption for wireless privacy at the dawn of quantum computing - UC Riverside

Quantum teleportation is an important step in improving quantum computing.

Beam me up is one of the most famous catchphrases from the Star Trek series. It is the command issued when a character wishes to teleport from a remote location back to the Starship Enterprise.

While human teleportation exists only in science fiction, teleportation is possible in the subatomic world of quantum mechanicsalbeit not in the way typically depicted on TV. In the quantum world, teleportation involves the transportation of information, rather than the transportation of matter.

Last year scientists confirmed that information could be passed between photons on computer chips even when the photons were not physically linked.

Now, according to new research from the University of Rochester and Purdue University, teleportation may also be possible between electrons.

A quantum processor semiconductor chip is connected to a circuit board in the lab of John Nichol, an assistant professor of physics at the University of Rochester. Nichol and Andrew Jordan, a professor of physics, are exploring new ways of creating quantum-mechanical interactions between distant electrons, promising major advances in quantum computing. Credit: University of Rochester photo / J. Adam Fenster

In a paper published in Nature Communications and one to appear in Physical Review X, the researchers, including John Nichol, an assistant professor of physics at Rochester, and Andrew Jordan, a professor of physics at Rochester, explore new ways of creating quantum-mechanical interactions between distant electrons. The research is an important step in improving quantum computing, which, in turn, has the potential to revolutionize technology, medicine, and science by providing faster and more efficient processors and sensors.

Quantum teleportation is a demonstration of what Albert Einstein famously called spooky action at a distancealso known as quantum entanglement. In entanglementone of the basic of concepts of quantum physicsthe properties of one particle affect the properties of another, even when the particles are separated by a large distance. Quantum teleportation involves two distant, entangled particles in which the state of a third particle instantly teleports its state to the two entangled particles.

Quantum teleportation is an important means for transmitting information in quantum computing. While a typical computer consists of billions of transistors, called bits, quantum computers encode information in quantum bits, or qubits. A bit has a single binary value, which can be either 0 or 1, but qubits can be both 0 and 1 at the same time. The ability for individual qubits to simultaneously occupy multiple states underlies the great potential power of quantum computers.

Scientists have recently demonstrated quantum teleportation by using electromagnetic photons to create remotely entangled pairs of qubits.

Qubits made from individual electrons, however, are also promising for transmitting information in semiconductors.

Individual electrons are promising qubits because they interact very easily with each other, and individual electron qubits in semiconductors are also scalable, Nichol says. Reliably creating long-distance interactions between electrons is essential for quantum computing.

Creating entangled pairs of electron qubits that span long distances, which is required for teleportation, has proved challenging, though: while photons naturally propagate over long distances, electrons usually are confined to one place.

In order to demonstrate quantum teleportation using electrons, the researchers harnessed a recently developed technique based on the principles of Heisenberg exchange coupling. An individual electron is like a bar magnet with a north pole and a south pole that can point either up or down. The direction of the polewhether the north pole is pointing up or down, for instanceis known as the electrons magnetic moment or quantum spin state. If certain kinds of particles have the same magnetic moment, they cannot be in the same place at the same time. That is, two electrons in the same quantum state cannot sit on top of each other. If they did, their states would swap back and forth in time.

The researchers used the technique to distribute entangled pairs of electrons and teleport their spin states.

We provide evidence for entanglement swapping, in which we create entanglement between two electrons even though the particles never interact, and quantum gate teleportation, a potentially useful technique for quantum computing using teleportation, Nichol says. Our work shows that this can be done even without photons.

The results pave the way for future research on quantum teleportation involving spin states of all matter, not just photons, and provide more evidence for the surprisingly useful capabilities of individual electrons in qubit semiconductors.

References:

Conditional teleportation of quantum-dot spin states by Haifeng Qiao, Yadav P. Kandel, Sreenath K. Manikandan, Andrew N. Jordan, Saeed Fallahi, Geoffrey C. Gardner, Michael J. Manfra and John M. Nichol, 15 June 2020, Nature Communications.DOI: 10.1038/s41467-020-16745-0

Coherent multi-spin exchange in a quantum-dot spin chain by Haifeng Qiao, Yadav P. Kandel, Kuangyin Deng, Saeed Fallahi, Geoffrey C. Gardner, Michael J. Manfra, Edwin Barnes, John M. Nichol, Accepted 12 May 2020, Physical Review X.arXiv: 2001.02277

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Teleportation Is Indeed Possible At Least in the Quantum World - SciTechDaily

Ed Heinbockel, president and chief executive officer of SavantX, said hes excited about how a powerful new generation of quantum computers can bring practical solutions to industries such as trucking and cargo transport.

With quantum computing, Im very keen on this, because Im a firm believer that its a step change technology, Heinbockel said. Its going to rewrite the way that we live and the way we work.

Heinbockel referred to recent breakthroughs such as Googles quantum supremacy, a demonstration where a programmable quantum processor solved a problem that no classical computer could feasibly solve.

In October 2019, Googles quantum processor, named Sycamore, performed a computation in 200 seconds that would have taken the worlds fastest supercomputer 10,000 years to solve, according to Google.

Jackson, Wyoming-based SavantX also recently formed a partnership with D-Wave Systems Inc., a Burnaby, Canada-based company that develops and offers quantum computing systems, software and services.

With D-Waves quantum services, SavantX has begun offering its Hyper Optimization Nodal Efficiency (HONE) technology to solve optimization problems to customers such as the Pier 300 container terminal project at the Port of Los Angeles.

The project, which began last year, is a partnership between SavantX, Blume Global and Fenix Marine Services. The projects goal is to optimize logistics on the spacing and placement of shipping containers to better integrate with inbound trucks and freight trains. The Pier 300 site handles 1.2 million container lifts per year.

With Pier 300, when do you need trucks at the pier and when and how do you get them scheduled optimally?, Heinbockel said. So the appointing part of it is very important and that is a facet of HONE technology.

Heinbockel added, Were very excited about the Pier 300 project, because HONE is a generalized technology. Then its a question of what other systems can we optimize? In all modes of transportation, the winners are going to be those that can minimize the energy in the systems; energy reduction. Thats all about optimization.

Heinbockel co-founded SavantX in 2015 with David Ostby, the companys chief science officer. SavantX offers data collection and visualization tools for industries ranging from healthcare to nuclear energy to transportation.

Heinbockel also recently announced SavantX will be relocating its corporate research headquarters to Santa Fe, New Mexico. The new center, which could eventually include 100 employees, will be focused on the companys HONE technology and customizing it for individual clients.

Heinbockel said SavantX has been talking to trucking, transportation and aviation companies about how HONE can help solve issues such as driver retention and optimizing schedules.

One of the problems Ive been hearing consistently from trucking companies is that they hire somebody. The HR department tells the new employee well have you home every Thursday night, Heinbockel said. Then you get onto a Friday night or Saturday, and [the driver] is still not home.

Heinbockel said if quantum computing and HONE can be used to help trucking companies with driver retention, and that it will make a lot of companies happy.

Heinbockel said cross-border operations could use HONE to understand what the flow patterns are like for commercial trucks crossing through different ports at various times of the day.

You would optimize your trucking flow based on when those lax periods were at those various ports, or you could ask yourself, is it cheaper for me to send a truck 100 miles out of the way to another port, knowing that it can get right through that port without having to sit for two or three hours in queue, Heinbockel said.

Click for more FreightWaves articles byNoi Mahoney.

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Tech company uses quantum computers to help shipping and trucking industries - FreightWaves

(iStockphoto)

Kelsea Best, a Ph.D. student in Earth and Environmental Sciences, has been awarded a graduate student pursuit grant from the National Socio-Environmental Synthesis Center to study the human impacts of climate change. Best is leading a team of graduate students fromseveral universities across the U.S. to study connections between climate change and displacement of people in coastal areas of the United States, with financial support for travel, high-performance computational resources and stipends provided by SESYNC.

David Curie, a third-year physics Ph.D. student, has received anOffice of Science Graduate Student Research Fellowshipto conduct part of his dissertation research in a Department of Energy laboratory. Curies work focuses on single-photon sources, which can be used inquantum communicationsand possibly quantum computing.

E. Bronson Ingram College was named the Best Higher Education/Research project for 2019 by Engineering News-Record magazine.

Brandt Eichman, William R. Kenan, Jr. Chair in Biological Sciences and professor of biochemistry, will receive the 2021 International Award from the Biochemical Society, the United Kingdoms leading organization of biochemists. The award, whichrecognizes outstanding and independent research that demonstrates the importance of the molecular biosciences, is given annually to an early- to mid-career scientist who has conducted research outside the U.K. and Ireland.

Mary Jo Gilmer, professor of nursing, has been selected for induction into the International Nurse Researcher Hall of Fame by Sigma Theta Tau International Honor Society of Nursing. The honor, which recognizes significant, sustained international achievement, is considered one of the highest honors in nursing research.

Kathryn Humphreys, assistant professor of psychology and human development, has received a 2020 Janet Taylor Spence Award from the Association for Psychological Science. The award recognizes early-career researchers who have made transformative contributions to the field of psychological science, such as establishing new paradigms within a subject area or advancing research that cuts across fields of study.

Karan Jani, a postdoctoral scholar in the Department of Physics and Astronomy, has been recognized as an All-Star Alumnus by Forbes for his research on black holes. Jani was named to Forbes30 Under 30Science list in 2017.

Jonathan Metzl, Frederick B. Rentschler II Professor of Sociology and Medicine, Health and Society, has received the 2020 Benjamin Rush Award from the American Psychiatric Association. The award recognizes an individual who has made significant contributions to the literature on the history of psychiatry.

Dawool (Lauren) Nam, a senior majoring in chemistry, has received the 2019-20 Girls in STEM Scholarship Award from Girls Who STEM, the mission of which is to increase access and participation of girls in STEM fields and to promote and support girls and women in STEM projects, areas of study and professions.

Roberta Nelson, assistant director of the Office of LGBTQI Life, has received the Promising New Professional Award from the Consortium of LGBT Resource Professionals. The award recognizes a professional with less than five years of experience for outstanding service, innovative or creative effort within the profession, and demonstration of significant promise for leadership in the field.

Laura Nichols, a first-year physics Ph.D. student, has received a Computational Science Graduate Fellowship in overall support of her dissertation research in computational physics. TheCSGF fellowship, awarded to only about 30 individuals nationally per year, supports Ph.D. candidates in the computational sciencesthose who use computer programming to solve problems in scientific disciplines such as physics, biology and chemistry.

Sokrates Pantelides, William A. and Nancy F. McMinn Professor of Physics and professor of electrical engineering, was one of three international scientists honored with the 2019 Award for International Scientific Cooperation by the Chinese Academy of Sciences. A pioneer in the field of semiconductor physics, Pantelides has carried out substantive cooperation with the CAS in developing new low-dimensional materials over the past two decades. In addition, Pantelides was named an honorary professor by Galgotias University in Greater Noida, Uttar Pradesh, India, in conjunction with a talk he gave at an Institute of Electrical and Electronics Engineers conference in nearby Lucknow.

Cleo Rucker, director of human resources consulting, employee and labor relations, has been appointed to the Metro Nashville Employee Benefits Study and Formulating Committee by Mayor John Cooper. The committees charge is to study and formulate a plan for employee benefits, including disability and retirement benefits, for Metro Nashville employees.

Keivan Stassun, Stevenson Chair in Physics and professor of astronomy and computer science, has been named an inaugural fellow of the American Astronomical Society, the major organization of professional astronomers in North America. The designation recognizes AAS members for extraordinary achievement and service, such as original research and publication, innovative contributions to astronomical techniques or instrumentation, significant contributions to education and public outreach, and noteworthy service to astronomy and to the society itself.

Steven Townsend, assistant professor of chemistry, has been named a Camille Dreyfus Teacher-Scholar for 2020. These faculty are within the first five years of their academic careers, have created an outstanding independent body of scholarship, and are deeply committed to education.

Kip Viscusi, University Distinguished Professor of Law, Economics and Management, has received the American Risk and Insurance Associations 2020 Kulp-Wright Book Award for Pricing Lives: Guideposts for a Safer Society. The award recognizes a risk management and insurance book or monograph that advances the body of knowledge toward new frontiers.

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Kudos: Read about faculty, staff and student awards, appointments and achievements - Vanderbilt University News

The camera crew was given full access to Earnest-Nobles research. In several scenes, Earnest-Noble is suited up in white PPE in the Pritzker Nanofabrication Facility in the Eckhardt Research Center. His scientific process and the breakthrough he seeks are depicted with animations and close-up footage of the state-of-the-art facilities. The filmmakers capture Earnest-Noble in the midst of a failed attempt or among his graveyard of failed quantum devices. As he embraces his doubts and is propelled by tenacity, viewers witness an emotional depiction of real science.

Earnest-Nobles lively interviews focus on the experience versus the result of his labors, providing a realistic portrayal of graduate studies and enabling viewers to follow him to his goal of identifying the ideal qubit for superpositiona phenomenon in quantum mechanics in which a particle can exist in several states at once.

When we were filming, I was trying to explain a qubit or something, and how much I was using jargon words was eye-opening to me. It helped me appreciate the challenge of making science understandable, said Earnest-Noble, who is now a quantum computing researcher at IBM. Science is a process far more than a series of facts. That became clear to me from working on this project.

Science communications typically takes a very long struggle of discovery and wraps it up into a pretty package, said Schuster. But something I found very special in this story is that you got to follow Nate for a couple of years. It accurately captured what Nates experience was like. And it focused on his experience, and not on the result, which is pretty amazing."

STAGEs director of science Sunanda Prabhu-Gaunkar originally joined the STAGE lab as a postdoc, and taught herself filmmaking in order to create the series. The scientific process inspires our filmmaking, she said. The workflow embraces failure, remains receptive to discoveries through iteration, and allows for risk-taking, all within a highly collaborative process.

Ellen Askey, the pilot episodes co-director, joined the project as a first-year student at UChicago with prior filmmaking experience. She worked on the series across her college career, graduating in June with a degree in cinema and media studies. Showing a story develop over time can be powerful, she said. We hope to get it out there to a lot of people who are and who are not yet interested in science.

Interested attendees can register through Eventbrite.

Adapted from an article by Maureen McMahon posted on the Physical Sciences Division website.

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Docuseries takes viewers into the lives and labs of scientists - UChicago News

This research report on the Global Quantum Computing for Enterprise Market provides an in-depth analysis of the market share, industry size, and current and future market trends. The Quantum Computing for Enterprise market report majorly sheds light on the market scope, growth prospects, potential, and the historical data of the market. TheQuantum Computing for Enterprise market report offers a complete segmentation depending on the factors such as end-use, type, application, and geographical regions that offer the assessment of every aspect of the Quantum Computing for Enterprise market. Similarly, the Quantum Computing for Enterprise report contains the market share on the basis of current as well as forecasted Quantum Computing for Enterprise market growth.

This study covers following key players:1QB Information TechnologiesAirbusAnyon SystemsCambridge Quantum ComputingD-Wave SystemsGoogleMicrosoftIBMIntelQC WareQuantumRigetti ComputingStrangeworksZapata Computing

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Market segment by Type, the product can be split into HardwareSoftware

Market segment by Application, split into BFSITelecommunications and ITRetail and E-CommerceGovernment and DefenseHealthcareManufacturingEnergy and UtilitiesConstruction and EngineeringOthers

Moreover, the retailers, exporters, and the leading service providers over the globe are also provided in the Quantum Computing for Enterprise market report along with their data such as price, product capacity, company profile, product portfolio, market revenue, and the cost of the product. Likewise, the graphical description and suitable figures of the Quantum Computing for Enterprise industry are also featured in this report. This research report also gives data like sales revenue, industry value & volume, upstream & downstream buyers, and industry chain formation. Likewise, the Quantum Computing for Enterprise market study offers an extensiveview of the changing market dynamics, market trends, restraints, driving factors, changing patterns, as well as restrictions of the market. The Quantum Computing for Enterprise market study is designed through quantitative and qualitative research techniques that majorly shed light on the industry growth and various challenges facing by the leading competitors along with the gap analysis and beneficial opportunities provided by the Quantum Computing for Enterprise market.

Some Major TOC Points:1 Report Overview2 Global Growth Trends3 Market Share by Key Players4 Breakdown Data by Type and ApplicationContinued

The Quantum Computing for Enterprise research study is a helpful analysis which emphasizing on geographical analysis, primary & secondary research methodologies, market drivers, and leading segmentation and sub-segments analysis. With the whole overview of the Quantum Computing for Enterprise market, the studyprovides the overall viability of future projects and delivers the Quantum Computing for Enterprise report conclusion. The Quantum Computing for Enterprise market report also delivers market evaluationalong with the PESTEL, SWOT, and other necessary data. In addition, the Quantum Computing for Enterprise market study categorizes the global market data by using numerous factors such as application, region, manufacturers, and type.

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Global Quantum Computing for Enterprise Market Expected to Reach Highest CAGR by 2025 Top Players: 1QB Information Technologies, Airbus, Anyon...