Quantum mechanics is the body of scientific laws that describe the wacky behavior of photons, electrons and the other particles that make up the universe.
Quantum mechanics is the branch of physics relating to the very small.
It results in what may appear to be some very strange conclusions about the physical world. At the scale of atoms and electrons, many of the equations ofclassical mechanics, which describe how things move at everyday sizes and speeds, cease to be useful. In classical mechanics, objects exist in a specific place at a specific time. However, in quantum mechanics, objects instead exist in a haze of probability; they have a certain chance of being at point A, another chance of being at point B and so on.
Quantum mechanics (QM) developed over many decades, beginning as a set of controversial mathematical explanations of experiments that the math of classical mechanics could not explain. It began at the turn of the 20th century, around the same time that Albert Einstein published histheory of relativity, a separate mathematical revolution in physics that describes the motion of things at high speeds. Unlike relativity, however, the origins of QM cannot be attributed to any one scientist. Rather, multiple scientists contributed to a foundation of three revolutionary principles that gradually gained acceptance and experimental verification between 1900 and 1930. They are:
Quantized properties: Certain properties, such as position, speed and color, can sometimes only occur in specific, set amounts, much like a dial that "clicks" from number to number. This challenged a fundamental assumption of classical mechanics, which said that such properties should exist on a smooth, continuous spectrum. To describe the idea that some properties "clicked" like a dial with specific settings, scientists coined the word "quantized."
Particles of light: Light can sometimes behave as a particle. This was initially met with harsh criticism, as it ran contrary to 200 years of experiments showing that light behaved as a wave; much like ripples on the surface of a calm lake. Light behaves similarly in that it bounces off walls and bends around corners, and that the crests and troughs of the wave can add up or cancel out. Added wave crests result in brighter light, while waves that cancel out produce darkness. A light source can be thought of as a ball on a stick beingrhythmically dipped in the center of a lake. The color emitted corresponds to the distance between the crests, which is determined by the speed of the ball's rhythm.
Waves of matter: Matter can also behave as a wave. This ran counter to the roughly 30 years of experiments showing that matter (such as electrons) exists as particles.
In 1900, German physicist Max Planck sought to explain the distribution of colors emitted over the spectrum in the glow of red-hot and white-hot objects, such as light-bulb filaments. When making physical sense of the equation he had derived to describe this distribution, Planck realized it implied that combinations of only certaincolors(albeit a great number of them) were emitted, specifically those that were whole-number multiples of some base value. Somehow, colors were quantized! This was unexpected because light was understood to act as a wave, meaning that values of color should be a continuous spectrum. What could be forbiddingatomsfrom producing the colors between these whole-number multiples? This seemed so strange that Planck regarded quantization as nothing more than a mathematical trick. According to Helge Kragh in his 2000 article in Physics World magazine, "Max Planck, the Reluctant Revolutionary," "If a revolution occurred in physics in December 1900, nobody seemed to notice it. Planck was no exception "
Planck's equation also contained a number that would later become very important to future development of QM; today, it's known as "Planck's Constant."
Quantization helped to explain other mysteries of physics. In 1907, Einstein used Planck's hypothesis of quantization to explain why the temperature of a solid changed by different amounts if you put the same amount of heat into the material but changed the starting temperature.
Since the early 1800s, the science ofspectroscopyhad shown that different elements emit and absorb specific colors of light called "spectral lines." Though spectroscopy was a reliable method for determining the elements contained in objects such as distant stars, scientists were puzzled aboutwhyeach element gave off those specific lines in the first place. In 1888, Johannes Rydberg derived an equation that described the spectral lines emitted by hydrogen, though nobody could explain why the equation worked. This changed in 1913 whenNiels Bohrapplied Planck's hypothesis of quantization to Ernest Rutherford's 1911 "planetary" model of the atom, which postulated that electrons orbited the nucleus the same way that planets orbit the sun. According toPhysics 2000(a site from the University of Colorado), Bohr proposed that electrons were restricted to "special" orbits around an atom's nucleus. They could "jump" between special orbits, and the energy produced by the jump caused specific colors of light, observed as spectral lines. Though quantized properties were invented as but a mere mathematical trick, they explained so much that they became the founding principle of QM.
In 1905, Einstein published a paper, "Concerning an Heuristic Point of View Toward the Emission and Transformation of Light," in which he envisioned light traveling not as a wave, but as some manner of "energy quanta." This packet of energy, Einstein suggested, could "be absorbed or generated only as a whole," specifically when an atom "jumps" between quantized vibration rates. This would also apply, as would be shown a few years later, when an electron "jumps" between quantized orbits. Under this model, Einstein's "energy quanta" contained the energy difference of the jump; when divided by Plancks constant, that energy difference determined the color of light carried by those quanta.
With this new way to envision light, Einstein offered insights into the behavior of nine different phenomena, including the specific colors that Planck described being emitted from a light-bulb filament. It also explained how certain colors of light could eject electrons off metal surfaces, a phenomenon known as the "photoelectric effect." However, Einstein wasn't wholly justified in taking this leap, said Stephen Klassen, an associate professor of physics at the University of Winnipeg. In a 2008 paper, "The Photoelectric Effect: Rehabilitating the Story for the Physics Classroom," Klassen states that Einstein's energy quanta aren't necessary for explaining all of those nine phenomena. Certain mathematical treatments of light as a wave are still capable of describing both the specific colors that Planck described being emitted from a light-bulb filament and the photoelectric effect. Indeed, in Einstein's controversial winning of the 1921Nobel Prize, the Nobel committee only acknowledged "his discovery of the law of the photoelectric effect," which specifically did not rely on the notion of energy quanta.
Roughly two decades after Einstein's paper, the term "photon" was popularized for describing energy quanta, thanks to the 1923 work of Arthur Compton, who showed that light scattered by an electron beam changed in color. This showed that particles of light (photons) were indeed colliding with particles of matter (electrons), thus confirming Einstein's hypothesis. By now, it was clear that light could behave both as a wave and a particle, placing light's "wave-particle duality" into the foundation of QM.
Since the discovery of the electron in 1896, evidence that all matter existed in the form of particles was slowly building. Still, the demonstration of light's wave-particle duality made scientists question whether matter was limited to actingonlyas particles. Perhaps wave-particle duality could ring true for matter as well? The first scientist to make substantial headway with this reasoning was a French physicist named Louis de Broglie. In 1924, de Broglie used the equations of Einstein'stheory of special relativityto show that particles can exhibit wave-like characteristics, and that waves can exhibit particle-like characteristics. Then in 1925, two scientists, working independently and using separate lines of mathematical thinking, applied de Broglie's reasoning to explain how electrons whizzed around in atoms (a phenomenon that was unexplainable using the equations ofclassical mechanics). In Germany, physicist Werner Heisenberg (teaming with Max Born and Pascual Jordan) accomplished this by developing "matrix mechanics." Austrian physicist ErwinSchrdingerdeveloped a similar theory called "wave mechanics." Schrdinger showed in 1926 that these two approaches were equivalent (though Swiss physicist Wolfgang Pauli sent anunpublished resultto Jordan showing that matrix mechanics was more complete).
The Heisenberg-Schrdinger model of the atom, in which each electron acts as a wave (sometimes referred to as a "cloud") around the nucleus of an atom replaced the Rutherford-Bohr model. One stipulation of the new model was that the ends of the wave that forms an electron must meet. In "Quantum Mechanics in Chemistry, 3rd Ed." (W.A. Benjamin, 1981), Melvin Hanna writes, "The imposition of the boundary conditions has restricted the energy to discrete values." A consequence of this stipulation is that only whole numbers of crests and troughs are allowed, which explains why some properties are quantized. In the Heisenberg-Schrdinger model of the atom, electrons obey a "wave function" and occupy "orbitals" rather than orbits. Unlike the circular orbits of the Rutherford-Bohr model, atomic orbitals have a variety of shapes ranging from spheres to dumbbells to daisies.
In 1927, Walter Heitler and Fritz London further developed wave mechanics to show how atomic orbitals could combine to form molecular orbitals, effectively showing why atoms bond to one another to formmolecules. This was yet another problem that had been unsolvable using the math of classical mechanics. These insights gave rise to the field of "quantum chemistry."
Also in 1927, Heisenberg made another major contribution to quantum physics. He reasoned that since matter acts as waves, some properties, such as an electron's position and speed, are "complementary," meaning there's a limit (related to Planck's constant) to how well the precision of each property can be known. Under what would come to be called "Heisenberg'suncertainty principle," it was reasoned that the more precisely an electron's position is known, the less precisely its speed can be known, and vice versa. This uncertainty principle applies to everyday-size objects as well, but is not noticeable because the lack of precision is extraordinarily tiny. According to Dave Slaven of Morningside College (Sioux City, IA), if a baseball's speed is known to within aprecision of 0.1 mph, the maximum precision to which it is possible to know the ball's position is 0.000000000000000000000000000008 millimeters.
The principles of quantization, wave-particle duality and the uncertainty principle ushered in a new era for QM. In 1927, Paul Dirac applied a quantum understanding of electric and magnetic fields to give rise to the study of "quantum field theory" (QFT), which treated particles (such as photons and electrons) as excited states of an underlying physical field. Work in QFT continued for a decade until scientists hit a roadblock: Many equations in QFT stopped making physical sense because they produced results of infinity. After a decade of stagnation, Hans Bethe made a breakthrough in 1947 using a technique called "renormalization." Here, Bethe realized that all infinite results related to two phenomena (specifically "electron self-energy" and "vacuum polarization") such that the observed values of electron mass and electron charge could be used to make all the infinities disappear.
Since the breakthrough of renormalization, QFT has served as the foundation for developing quantum theories about the four fundamental forces of nature: 1) electromagnetism, 2) the weak nuclear force, 3) the strong nuclear force and 4) gravity. The first insight provided by QFT was a quantum description of electromagnetism through "quantum electrodynamics" (QED), which made strides in the late 1940s and early 1950s. Next was a quantum description of the weak nuclear force, which was unified with electromagnetism to build "electroweak theory" (EWT) throughout the 1960s. Finally came a quantum treatment of the strong nuclear force using "quantum chromodynamics" (QCD) in the 1960s and 1970s. The theories of QED, EWT and QCD together form the basis of theStandard Modelof particle physics. Unfortunately, QFT has yet to produce a quantum theory of gravity. That quest continues today in the studies of string theory and loop quantum gravity.
Robert Coolman is a graduate researcher at the University of Wisconsin-Madison, finishing up his Ph.D. in chemical engineering. He writes about math, science and how they interact with history. Follow Robert@PrimeViridian. Followus@LiveScience,Facebook&Google+.
See the article here:
What Is Quantum Mechanics? - livescience.com
- Physicists breed Schrdinger's cats to find boundaries of the | Cosmos - Cosmos [Last Updated On: May 3rd, 2017] [Originally Added On: May 3rd, 2017]
- The application of three-axis low energy spectroscopy in quantum physics research - Phys.Org [Last Updated On: May 3rd, 2017] [Originally Added On: May 3rd, 2017]
- Scientists 'BREED' Schrodinger's Cat in massive quantum physics breakthrough - Express.co.uk [Last Updated On: May 3rd, 2017] [Originally Added On: May 3rd, 2017]
- Quantum Physics: Are Entangled Particles Connected Via An Undetected Dimension? - Forbes [Last Updated On: May 3rd, 2017] [Originally Added On: May 3rd, 2017]
- The World Of Quantum Physics: EVERYTHING Is Energy : In5D ... [Last Updated On: May 3rd, 2017] [Originally Added On: May 3rd, 2017]
- Introduction to quantum mechanics - Wikipedia [Last Updated On: May 3rd, 2017] [Originally Added On: May 3rd, 2017]
- A general election, like quantum physics, is a thing of waves and particles - The Tablet [Last Updated On: May 4th, 2017] [Originally Added On: May 4th, 2017]
- 14-Year-Old Earns Physics Degree From TCU CBS Dallas / Fort ... - CBS DFW [Last Updated On: May 11th, 2017] [Originally Added On: May 11th, 2017]
- Quantum Entanglement Persists Even Under High Accelerations ... - International Business Times [Last Updated On: May 11th, 2017] [Originally Added On: May 11th, 2017]
- Quantum Entanglement Persists Even Under High Accelerations, Experiments Reveal - International Business Times [Last Updated On: May 11th, 2017] [Originally Added On: May 11th, 2017]
- Quantum - Wikipedia [Last Updated On: May 11th, 2017] [Originally Added On: May 11th, 2017]
- Unbreakable quantum entanglement - Phys.Org [Last Updated On: May 11th, 2017] [Originally Added On: May 11th, 2017]
- Physics may bring faster solutions for tough computational problems - Phys.Org [Last Updated On: May 14th, 2017] [Originally Added On: May 14th, 2017]
- UBC researchers propose answer to fundamental space problem - CBC.ca [Last Updated On: May 17th, 2017] [Originally Added On: May 17th, 2017]
- Quantum Biology and the Frog Prince - ScienceBlog.com (blog) [Last Updated On: May 18th, 2017] [Originally Added On: May 18th, 2017]
- The Marriage Of Einstein's Theory Of Relativity And Quantum Physics Depends On The Pull Of Gravity - Forbes [Last Updated On: May 18th, 2017] [Originally Added On: May 18th, 2017]
- New Research May Reconcile General Relativity and Quantum Mechanics - Futurism [Last Updated On: May 18th, 2017] [Originally Added On: May 18th, 2017]
- The Bizarre Quantum Test That Could Keep Your Data Secure - WIRED [Last Updated On: May 20th, 2017] [Originally Added On: May 20th, 2017]
- Testing quantum field theory in a quantum simulator - Phys.org - Phys.Org [Last Updated On: May 20th, 2017] [Originally Added On: May 20th, 2017]
- A classic quantum test could reveal the limits of the human mind - New Scientist [Last Updated On: May 20th, 2017] [Originally Added On: May 20th, 2017]
- Teleportation Could Be Possible Using Quantum Physics - Futurism - Futurism [Last Updated On: May 22nd, 2017] [Originally Added On: May 22nd, 2017]
- Nobel winner to talk cats, computers and quantum physics - AroundtheO [Last Updated On: May 23rd, 2017] [Originally Added On: May 23rd, 2017]
- Could Ant-Man Beat Superman With Quantum Physics? - Heroic Hollywood (blog) [Last Updated On: May 26th, 2017] [Originally Added On: May 26th, 2017]
- Physicists Discover Geometry Underlying Particle Physics [Last Updated On: May 26th, 2017] [Originally Added On: May 26th, 2017]
- Home - Center for Quantum Activism [Last Updated On: May 26th, 2017] [Originally Added On: May 26th, 2017]
- Physics - Wikipedia [Last Updated On: May 26th, 2017] [Originally Added On: May 26th, 2017]
- What Quantum Physics Can Tell Us about the Afterlife ... [Last Updated On: May 26th, 2017] [Originally Added On: May 26th, 2017]
- A Quantum Physicist Explains How Ant-Man Can Beat Superman - Inverse [Last Updated On: May 28th, 2017] [Originally Added On: May 28th, 2017]
- Academic Journal: Quantum Physics Is 'Oppressive' to Marginalized People - National Review [Last Updated On: May 30th, 2017] [Originally Added On: May 30th, 2017]
- University of Arizona Scholar Creates a Feminist Brand of Physics to ... - Breitbart News [Last Updated On: June 1st, 2017] [Originally Added On: June 1st, 2017]
- Feminist Launches 'Intersectional Quantum Physics' to End Newton's 'Oppression' - PJ Media [Last Updated On: June 1st, 2017] [Originally Added On: June 1st, 2017]
- In atomic propellers, quantum phenomena can mimic everyday ... - Phys.Org [Last Updated On: June 1st, 2017] [Originally Added On: June 1st, 2017]
- Quantum physics is oppressive - Patheos - Patheos (blog) [Last Updated On: June 5th, 2017] [Originally Added On: June 5th, 2017]
- It's widely abused as a buzzword. But can quantum mechanics explain how we think? - National Post [Last Updated On: June 5th, 2017] [Originally Added On: June 5th, 2017]
- Quantum Physics and Love are Super Weird and Confusing, but This Play Makes Sense of Them Both - LA Magazine [Last Updated On: June 6th, 2017] [Originally Added On: June 6th, 2017]
- One step closer to the quantum internet by distillation - Phys.Org [Last Updated On: June 7th, 2017] [Originally Added On: June 7th, 2017]
- Solving systems of linear equations with quantum mechanics - Phys.Org [Last Updated On: June 10th, 2017] [Originally Added On: June 10th, 2017]
- Neural networks take on quantum entanglement - Phys.Org [Last Updated On: June 14th, 2017] [Originally Added On: June 14th, 2017]
- Chinese satellite breaks a quantum physics record, beams entangled photons from space to Earth - Los Angeles Times [Last Updated On: June 15th, 2017] [Originally Added On: June 15th, 2017]
- Cybersecurity Attacks Are a Global Threat. Chinese Scientists Have the Answer: Quantum Mechanics - Newsweek [Last Updated On: June 16th, 2017] [Originally Added On: June 16th, 2017]
- New Quantum-Entanglement Record Could Spur Hack-Proof Communications - Yahoo News [Last Updated On: June 18th, 2017] [Originally Added On: June 18th, 2017]
- China sets new record for quantum entanglement en route to build new communication network - NEWS.com.au [Last Updated On: June 19th, 2017] [Originally Added On: June 19th, 2017]
- Physicists Demonstrate Record Breaking Long-Distance Quantum Entanglement in Space - Futurism [Last Updated On: June 21st, 2017] [Originally Added On: June 21st, 2017]
- Viewpoint: A Roadmap for a Scalable Topological Quantum Computer - Physics [Last Updated On: June 22nd, 2017] [Originally Added On: June 22nd, 2017]
- How Schrdinger's Cat Helps Explain the New Findings About the Quantum Zeno Effect - Futurism [Last Updated On: June 22nd, 2017] [Originally Added On: June 22nd, 2017]
- BMW and Volkswagen Try to Beat Apple and Google at Their Own Game - New York Times [Last Updated On: June 23rd, 2017] [Originally Added On: June 23rd, 2017]
- How quantum physics could revolutionize casinos and betting if you can understand it - Casinopedia [Last Updated On: June 23rd, 2017] [Originally Added On: June 23rd, 2017]
- Quantum thermometer or optical refrigerator? - Phys.org - Phys.Org [Last Updated On: June 23rd, 2017] [Originally Added On: June 23rd, 2017]
- Atomic imperfections move quantum communication network closer ... - Phys.Org [Last Updated On: June 24th, 2017] [Originally Added On: June 24th, 2017]
- DoE Launches Chicago Quantum Exchange - HPCwire (blog) [Last Updated On: June 26th, 2017] [Originally Added On: June 26th, 2017]
- Google to Achieve "Supremacy" in Quantum Computing by the End of 2017 - Big Think [Last Updated On: June 26th, 2017] [Originally Added On: June 26th, 2017]
- Physicists settle debate over how exotic quantum particles form - Phys.Org [Last Updated On: June 27th, 2017] [Originally Added On: June 27th, 2017]
- Physicists make quantum leap in understanding life's nanoscale machinery - Phys.Org [Last Updated On: June 27th, 2017] [Originally Added On: June 27th, 2017]
- How quantum trickery can scramble cause and effect - Nature.com [Last Updated On: June 28th, 2017] [Originally Added On: June 28th, 2017]
- Berkeley Lab Intern Finds Her Way in Particle Physics | Berkeley Lab - Lawrence Berkeley National Laboratory [Last Updated On: June 28th, 2017] [Originally Added On: June 28th, 2017]
- Quantum Physics News - Phys.org - News and Articles on ... [Last Updated On: June 28th, 2017] [Originally Added On: June 28th, 2017]
- Quantum computers are about to get real - Science News Magazine [Last Updated On: June 29th, 2017] [Originally Added On: June 29th, 2017]
- Physics4Kids.com: Modern Physics: Quantum Mechanics [Last Updated On: June 29th, 2017] [Originally Added On: June 29th, 2017]
- Payments Innovation - A Quantum World Of Payments - Finextra (blog) [Last Updated On: June 30th, 2017] [Originally Added On: June 30th, 2017]
- Why can't quantum theory and relativity get along? - Brantford Expositor [Last Updated On: June 30th, 2017] [Originally Added On: June 30th, 2017]
- New method could enable more stable and scalable quantum computing, physicists report - Phys.Org [Last Updated On: June 30th, 2017] [Originally Added On: June 30th, 2017]
- Telecommunications, Meet Quantum Physics - Electronics360 [Last Updated On: June 30th, 2017] [Originally Added On: June 30th, 2017]
- How young is too young to talk to kids about science? Never, says one quantum physicist - ABC Local [Last Updated On: July 9th, 2017] [Originally Added On: July 9th, 2017]
- Supercool breakthrough brings new quantum benchmark - Phys.org - Phys.Org [Last Updated On: July 9th, 2017] [Originally Added On: July 9th, 2017]
- Physics For Toddlers . News | OPB - OPB News [Last Updated On: July 9th, 2017] [Originally Added On: July 9th, 2017]
- Quantum Physics Provide Evidence that the Future Influences the Past - Edgy Labs (blog) [Last Updated On: July 9th, 2017] [Originally Added On: July 9th, 2017]
- This quantum theory predicts that the future might be influencing the ... - ScienceAlert [Last Updated On: July 9th, 2017] [Originally Added On: July 9th, 2017]
- Physicists May Have Discovered One of the Missing Pieces of Quantum Theory - Futurism [Last Updated On: July 9th, 2017] [Originally Added On: July 9th, 2017]
- Something New For Baby To Chew On: Rocket Science And ... - NPR - NPR [Last Updated On: July 9th, 2017] [Originally Added On: July 9th, 2017]
- A New Quantum Theory Predicts That the Future Could Be Influencing the Past - Big Think [Last Updated On: July 14th, 2017] [Originally Added On: July 14th, 2017]
- Basic Assumptions of Physics Might Require the Future to Influence ... - Gizmodo [Last Updated On: July 14th, 2017] [Originally Added On: July 14th, 2017]
- Scientists teleport particle into space in major breakthrough for quantum physics - The Independent [Last Updated On: July 14th, 2017] [Originally Added On: July 14th, 2017]
- Rockstar scientist David Reilly takes the axe to quantum physics - The Sydney Morning Herald [Last Updated On: July 14th, 2017] [Originally Added On: July 14th, 2017]
- Quantum Mechanics Could Shake Up Our Understanding of Earth's ... - Gizmodo [Last Updated On: July 14th, 2017] [Originally Added On: July 14th, 2017]
- The Standard Model of particle physics is brilliant and completely flawed - ABC Online [Last Updated On: July 17th, 2017] [Originally Added On: July 17th, 2017]
- Quantum mechanics inside Earth's core - Phys.org - Phys.Org [Last Updated On: July 17th, 2017] [Originally Added On: July 17th, 2017]
- Making a quantum leap in space research - Shanghai Daily (subscription) [Last Updated On: August 6th, 2017] [Originally Added On: August 6th, 2017]
- Unlocking the Secrets of Quantum Physics to Create New Materials - Yu News (blog) [Last Updated On: August 6th, 2017] [Originally Added On: August 6th, 2017]
- China's Silicon Valley aims to become the country's top research center - Abacus [Last Updated On: October 16th, 2019] [Originally Added On: October 16th, 2019]
- New Quantum-Mechanical Dissipation Mechanism Observed for the First Time - SciTechDaily [Last Updated On: October 16th, 2019] [Originally Added On: October 16th, 2019]