The history of quantum mechanics is a fundamental part of the history of modern physics. Quantum mechanics' history, as it interlaces with the history of quantum chemistry, began essentially with a number of different scientific discoveries: the 1838 discovery of cathode rays by Michael Faraday; the 185960 winter statement of the black-body radiation problem by Gustav Kirchhoff; the 1877 suggestion by Ludwig Boltzmann that the energy states of a physical system could be discrete; the discovery of the photoelectric effect by Heinrich Hertz in 1887; and the 1900 quantum hypothesis by Max Planck that any energy-radiating atomic system can theoretically be divided into a number of discrete "energy elements" (Greek letter epsilon) such that each of these energy elements is proportional to the frequency with which each of them individually radiate energy, as defined by the following formula:
where h is a numerical value called Planck's constant.
Then, Albert Einstein in 1905, in order to explain the photoelectric effect previously reported by Heinrich Hertz in 1887, postulated consistently with Max Planck's quantum hypothesis that light itself is made of individual quantum particles, which in 1926 came to be called photons by Gilbert N. Lewis. The photoelectric effect was observed upon shining light of particular wavelengths on certain materials, such as metals, which caused electrons to be ejected from those materials only if the light quantum energy was greater than the work function of the metal's surface.
The phrase "quantum mechanics" was coined (in German, Quantenmechanik) by the group of physicists including Max Born, Werner Heisenberg, and Wolfgang Pauli, at the University of Gttingen in the early 1920s, and was first used in Born's 1924 paper "Zur Quantenmechanik".[1] In the years to follow, this theoretical basis slowly began to be applied to chemical structure, reactivity, and bonding.
Ludwig Boltzmann suggested in 1877 that the energy levels of a physical system, such as a molecule, could be discrete (as opposed to continuous). He was a founder of the Austrian Mathematical Society, together with the mathematicians Gustav von Escherich and Emil Mller. Boltzmann's rationale for the presence of discrete energy levels in molecules such as those of iodine gas had its origins in his statistical thermodynamics and statistical mechanics theories and was backed up by mathematical arguments, as would also be the case twenty years later with the first quantum theory put forward by Max Planck.
In 1900, the German physicist Max Planck reluctantly introduced the idea that energy is quantized in order to derive a formula for the observed frequency dependence of the energy emitted by a black body, called Planck's law, that included a Boltzmann distribution (applicable in the classical limit). Planck's law[2] can be stated as follows: I ( , T ) = 2 h 3 c 2 1 e h k T 1 , {displaystyle I(nu ,T)={frac {2hnu ^{3}}{c^{2}}}{frac {1}{e^{frac {hnu }{kT}}-1}},} where:
The earlier Wien approximation may be derived from Planck's law by assuming h k T {displaystyle hnu gg kT} .
Moreover, the application of Planck's quantum theory to the electron allowed tefan Procopiu in 19111913, and subsequently Niels Bohr in 1913, to calculate the magnetic moment of the electron, which was later called the "magneton;" similar quantum computations, but with numerically quite different values, were subsequently made possible for both the magnetic moments of the proton and the neutron that are three orders of magnitude smaller than that of the electron.
In 1905, Albert Einstein explained the photoelectric effect by postulating that light, or more generally all electromagnetic radiation, can be divided into a finite number of "energy quanta" that are localized points in space. From the introduction section of his March 1905 quantum paper, "On a heuristic viewpoint concerning the emission and transformation of light", Einstein states:
"According to the assumption to be contemplated here, when a light ray is spreading from a point, the energy is not distributed continuously over ever-increasing spaces, but consists of a finite number of 'energy quanta' that are localized in points in space, move without dividing, and can be absorbed or generated only as a whole."
This statement has been called the most revolutionary sentence written by a physicist of the twentieth century.[3] These energy quanta later came to be called "photons", a term introduced by Gilbert N. Lewis in 1926. The idea that each photon had to consist of energy in terms of quanta was a remarkable achievement; it effectively solved the problem of black-body radiation attaining infinite energy, which occurred in theory if light were to be explained only in terms of waves. In 1913, Bohr explained the spectral lines of the hydrogen atom, again by using quantization, in his paper of July 1913 On the Constitution of Atoms and Molecules.
These theories, though successful, were strictly phenomenological: during this time, there was no rigorous justification for quantization, aside, perhaps, from Henri Poincar's discussion of Planck's theory in his 1912 paper Sur la thorie des quanta.[4][5] They are collectively known as the old quantum theory.
The phrase "quantum physics" was first used in Johnston's Planck's Universe in Light of Modern Physics (1931).
In 1923, the French physicist Louis de Broglie put forward his theory of matter waves by stating that particles can exhibit wave characteristics and vice versa. This theory was for a single particle and derived from special relativity theory. Building on de Broglie's approach, modern quantum mechanics was born in 1925, when the German physicists Werner Heisenberg, Max Born, and Pascual Jordan[6][7] developed matrix mechanics and the Austrian physicist Erwin Schrdinger invented wave mechanics and the non-relativistic Schrdinger equation as an approximation of the generalised case of de Broglie's theory.[8] Schrdinger subsequently showed that the two approaches were equivalent.
Heisenberg formulated his uncertainty principle in 1927, and the Copenhagen interpretation started to take shape at about the same time. Starting around 1927, Paul Dirac began the process of unifying quantum mechanics with special relativity by proposing the Dirac equation for the electron. The Dirac equation achieves the relativistic description of the wavefunction of an electron that Schrdinger failed to obtain. It predicts electron spin and led Dirac to predict the existence of the positron. He also pioneered the use of operator theory, including the influential braket notation, as described in his famous 1930 textbook. During the same period, Hungarian polymath John von Neumann formulated the rigorous mathematical basis for quantum mechanics as the theory of linear operators on Hilbert spaces, as described in his likewise famous 1932 textbook. These, like many other works from the founding period, still stand, and remain widely used.
The field of quantum chemistry was pioneered by physicists Walter Heitler and Fritz London, who published a study of the covalent bond of the hydrogen molecule in 1927. Quantum chemistry was subsequently developed by a large number of workers, including the American theoretical chemist Linus Pauling at Caltech, and John C. Slater into various theories such as Molecular Orbital Theory or Valence Theory.
Beginning in 1927, researchers attempted to apply quantum mechanics to fields instead of single particles, resulting in quantum field theories. Early workers in this area include P.A.M. Dirac, W. Pauli, V. Weisskopf, and P. Jordan. This area of research culminated in the formulation of quantum electrodynamics by R.P. Feynman, F. Dyson, J. Schwinger, and S. Tomonaga during the 1940s. Quantum electrodynamics describes a quantum theory of electrons, positrons, and the electromagnetic field, and served as a model for subsequent quantum field theories.[6][7][9]
The theory of quantum chromodynamics was formulated beginning in the early 1960s. The theory as we know it today was formulated by Politzer, Gross and Wilczek in 1975.
Building on pioneering work by Schwinger, Higgs and Goldstone, the physicists Glashow, Weinberg and Salam independently showed how the weak nuclear force and quantum electrodynamics could be merged into a single electroweak force, for which they received the 1979 Nobel Prize in Physics.
See more here:
History of quantum mechanics - Wikipedia
- Netflixs 3 Body Problem: The science explained by an astrophysicist - Vox.com - March 24th, 2024 [March 24th, 2024]
- Entanglement entropies of nuclear systems gro - EurekAlert - March 24th, 2024 [March 24th, 2024]
- The Quest for a Theory of Everything Scientists Put Einstein to the Test - SciTechDaily - March 24th, 2024 [March 24th, 2024]
- Vibrating atoms are seen 'tuning' the energy of a single electron - Earth.com - March 24th, 2024 [March 24th, 2024]
- Innovator Spotlight: Joseph Maciejko | The Quad - University of Alberta - March 24th, 2024 [March 24th, 2024]
- A Breakthrough in the Control of Quantum Phenomena at Room Temperature Has Been Achieved, Researchers Say - The Debrief - February 16th, 2024 [February 16th, 2024]
- The End of the Quantum Ice Age: Room Temperature Breakthrough - SciTechDaily - February 16th, 2024 [February 16th, 2024]
- Quantum computer outperformed by new traditional computing - Earth.com - February 16th, 2024 [February 16th, 2024]
- URI program to help STEM professionals pivot into quantum information science careers - The University of Rhode Island - February 16th, 2024 [February 16th, 2024]
- Quantum realm controlled at room temperature for the first time - Earth.com - February 16th, 2024 [February 16th, 2024]
- Quantum Breakthrough: New Method Preserves Information Against All Odds - SciTechDaily - February 16th, 2024 [February 16th, 2024]
- Quantum computers get new design that makes them more "useful" - Earth.com - February 16th, 2024 [February 16th, 2024]
- Beyond Classical Physics: Scientists Discover New State of Matter With Chiral Properties - SciTechDaily - February 16th, 2024 [February 16th, 2024]
- Quantum research sheds light on the mystery of high-temperature superconductivity - Tech Explorist - February 16th, 2024 [February 16th, 2024]
- Unlocking the Mysteries of Quantum Many-Body Systems: A Look at Quantum Simulators and Universal Scaling ... - Medriva - February 16th, 2024 [February 16th, 2024]
- Functioning quantum internet makes giant stride closer to reality - Earth.com - February 13th, 2024 [February 13th, 2024]
- Exploring New Futures in Space: A Revolutionary Integration of Neuroscience, Quantum Physics, and Space Exploration - SETI Institute - February 13th, 2024 [February 13th, 2024]
- Uncovering the Quantum Plateau: Significance and Implications | Nature Physics - Medriva - February 13th, 2024 [February 13th, 2024]
- The State of the Art in Quantum Computing - Medium - February 13th, 2024 [February 13th, 2024]
- Beyond the Visible Universe: New Research Reveals How Gravity Influences the Quantum Realm - SciTechDaily - February 13th, 2024 [February 13th, 2024]
- Leader of IBM's Quantum Safe Team to speak at URI - University of Rhode Island - September 23rd, 2023 [September 23rd, 2023]
- University Assistant Predoctoral, Physics job with UNIVERSITY OF ... - Times Higher Education - September 23rd, 2023 [September 23rd, 2023]
- Zentropy A New Theory That Could Transform Material Science - SciTechDaily - September 23rd, 2023 [September 23rd, 2023]
- Researchers Studying the Quantum Realm Observe Alice in ... - The Debrief - September 23rd, 2023 [September 23rd, 2023]
- Augusta University graduate starts business in the artificial ... - Jagwire Augusta - September 23rd, 2023 [September 23rd, 2023]
- Quantum Echoes: A Revolutionary Method to Store Information as Sound Waves - SciTechDaily - August 14th, 2023 [August 14th, 2023]
- 'Quantum superchemistry' observed for the 1st time ever - Space.com - August 14th, 2023 [August 14th, 2023]
- Quantum Avalanche A Phenomenon That May Revolutionize Microelectronics and Supercomputing - SciTechDaily - August 14th, 2023 [August 14th, 2023]
- Applications of quantum mechanics at the beach - Symmetry magazine - August 14th, 2023 [August 14th, 2023]
- Book Review: On the Origin of Time Stephen Hawking's Final Theory - Moose Jaw Today - August 14th, 2023 [August 14th, 2023]
- Harnessing Quantum Technologies: The Next Big Leap in Global ... - Fagen wasanni - August 14th, 2023 [August 14th, 2023]
- The quantum avalanche - At the Vienna University of Technology, it ... - Chemie.de - August 14th, 2023 [August 14th, 2023]
- Semiconductors: The Linchpin of AI in Quantum Computing - Fagen wasanni - August 14th, 2023 [August 14th, 2023]
- The Promising Collaboration Between AI and Quantum Computing - Fagen wasanni - August 14th, 2023 [August 14th, 2023]
- String theory physicist changed quantum field theory - USC Dornsife College of Letters, Arts and Sciences - August 14th, 2023 [August 14th, 2023]
- QUANTUM SUPERCOMPUTERS. The words Quantum and ... - Medium - August 14th, 2023 [August 14th, 2023]
- Fourteen MIT School of Science professors receive tenure for 2022 ... - MIT News - August 14th, 2023 [August 14th, 2023]
- The Fascinating World of Quantum Integrated Circuits: The Next Big ... - Fagen wasanni - August 14th, 2023 [August 14th, 2023]
- Conclusive Evidence for Modified Gravity: Collapse of Newton's and ... - SciTechDaily - August 14th, 2023 [August 14th, 2023]
- Physicists Open New Path to an Exotic Form of Superconductivity - SciTechDaily - August 14th, 2023 [August 14th, 2023]
- The Principle of Least Action Now Exists in the Quantum Realm - Popular Mechanics - June 10th, 2023 [June 10th, 2023]
- Quantum materials: Electron spin measured for the first time - EurekAlert - June 10th, 2023 [June 10th, 2023]
- Life in a hologram | MIT News | Massachusetts Institute of Technology - MIT News - June 10th, 2023 [June 10th, 2023]
- If Black Holes Evaporate, Everything Evaporates - Universe Today - June 10th, 2023 [June 10th, 2023]
- Clever Ant-Man Easter Egg Links The Movie to the Real World's ... - Startefacts - June 10th, 2023 [June 10th, 2023]
- Quantum Cryptography: The Cutting Edge of Secure Communication - CityLife - June 10th, 2023 [June 10th, 2023]
- This 17-year-old works to make quantum mainstream - Indiatimes.com - June 10th, 2023 [June 10th, 2023]
- The multiverse is doomed and even Spider-Man and The Flash can't save it - Yahoo Entertainment - June 10th, 2023 [June 10th, 2023]
- Physics of Time Travel: A Scientific Perspective - Mirage News - June 10th, 2023 [June 10th, 2023]
- Quantum Spin Liquids: The Future of Superconductors - EnergyPortal.eu - June 10th, 2023 [June 10th, 2023]
- Interview: Three Books That Make Tess Gunty Angry - The New York Times - June 10th, 2023 [June 10th, 2023]
- Events Calendar School of Mathematics and Statistics Colloquium ... - Carleton University - June 10th, 2023 [June 10th, 2023]
- Graphene and Quantum Computing: A Match Made in Heaven - CityLife - June 10th, 2023 [June 10th, 2023]
- A Quantum Computer Simulation Has Reversed Time And Physics May Never Be The Same - Twisted Sifter - June 2nd, 2023 [June 2nd, 2023]
- Realizing the Einstein-Podolsky-Rosen Paradox for Atomic Clouds - Physics - June 2nd, 2023 [June 2nd, 2023]
- The US and UK team up to advance quantum information science - Fermi National Accelerator Laboratory - June 2nd, 2023 [June 2nd, 2023]
- How plants can perform feats of quantum mechanics - Big Think - June 2nd, 2023 [June 2nd, 2023]
- Physicists Make Matter out of Light to Find Quantum Singularities - Scientific American - June 2nd, 2023 [June 2nd, 2023]
- Eventually everything will evaporate, not only black holes - Science Daily - June 2nd, 2023 [June 2nd, 2023]
- Julius-Maximillians-Universitt Wrzburg Researchers Use ... - HPCwire - June 2nd, 2023 [June 2nd, 2023]
- TNTs The Lazarus Project Uses Suspense Trapping to Ask Smart ... - Roger Ebert - June 2nd, 2023 [June 2nd, 2023]
- Quantum Exponential: building a cutting edge quantum technology ... - The Armchair Trader - June 2nd, 2023 [June 2nd, 2023]
- IMDEA Software and IMDEA Networks work to deploy in the ... - EurekAlert - June 2nd, 2023 [June 2nd, 2023]
- Ian Hacking, Eminent Philosopher of Science and Much Else, Dies ... - The New York Times - June 2nd, 2023 [June 2nd, 2023]
- Does mass increase when nearing the speed of light? - Big Think - June 2nd, 2023 [June 2nd, 2023]
- Answering Questions about Boring Numbers, Disasters, Fusion, and ... - Scientific American - June 2nd, 2023 [June 2nd, 2023]
- Spiderman: Across the Spider-verse | Reel World | timesnewspapers ... - Webster-Kirkwood Times, Inc. - June 2nd, 2023 [June 2nd, 2023]
- There's a Secret Way to Get to Absolute Zero. Scientists Just Found It. - Popular Mechanics - May 6th, 2023 [May 6th, 2023]
- Photon Precision: How Quantum Physicists Shattered the Bounds of Sensitivity - SciTechDaily - May 6th, 2023 [May 6th, 2023]
- Do we live in a hologram? Why physics is still mesmerised by this idea - New Scientist - May 6th, 2023 [May 6th, 2023]
- Is Ultimate Truth an Equation? Nah. The Stute - The Stute - May 6th, 2023 [May 6th, 2023]
- UChicago Lab Creates 'Quantum Casino,' a Win-Win to Educate and ... - Polsky Center for Entrepreneurship and Innovation - May 6th, 2023 [May 6th, 2023]
- Physics - Tweezers in Three Dimensions - Physics - May 6th, 2023 [May 6th, 2023]
- Brave new world: On the edge of a second quantum revolution - University of Cape Town News - May 6th, 2023 [May 6th, 2023]
- Researchers pull back the quantum curtain on 'Weyl fermions' - Phys.org - May 6th, 2023 [May 6th, 2023]
- Scale separation: Breaking down unsolvable problems into solvable ones - Phys.org - May 6th, 2023 [May 6th, 2023]
- Postdoctoral Research Associate in Quantum Optics job with ... - Times Higher Education - May 6th, 2023 [May 6th, 2023]
- Australia's first quantum strategy predicts $6 billion in revenue and ... - SmartCompany - May 6th, 2023 [May 6th, 2023]
- Nature's Quantum Secret: Link Discovered Between Photosynthesis ... - SciTechDaily - May 6th, 2023 [May 6th, 2023]
- Two ERC proof of concept grants for the University of Bonn - EurekAlert - May 6th, 2023 [May 6th, 2023]