//Important Dates in Quantum Mechanics, Molecular Physics, Atomic Physics, Nuclear Physics, and Particle Physics
//Prepared on October 25,2002
//Source: http://www.gsu.edu/other/timeline/quantum.html
//copied directly from the web page of William Nielsen Brandt
//Data as presented is Copyrighted by Niel Brandt 1994. 
//By KeH
//CSE 143 JH TA:Kuang Chen
//Homework 2
1766
Henry Cavendish discovers and studies hydrogen
1778
Carl Scheele and Antoine Lavoisier discover that air is composed mostly of nitrogen and oxygen
1781
Joseph Priestly creates water by igniting hydrogen and oxygen
1800
William Nicholson and Anthony Carlisle use electrolysis to separate water into hydrogen and oxygen
1803
John Dalton introduces atomic ideas into chemistry and states that matter is composed of atoms of different weights
1811
Amedeo Avogadro claims that equal volumes of gases should contain equal numbers of molecules
1832
Michael Faraday states his laws of electrolysis
1871
Dmitri Mendeleyev systematically examines the periodic table and predicts the existence of gallium, scandium, and germanium
1873
Johannes van der Waals introduces the idea of weak attractive forces between molecules
1885
Johann Balmer finds a mathematical expression for observed hydrogen line wavelengths
1887
Heinrich Hertz discovers the photoelectric effect
1894
Lord Rayleigh and William Ramsay discover argon by spectroscopically analyzing the gas left over after nitrogen and oxygen are removed from air
1895
William Ramsay discovers terrestrial helium by spectroscopically analyzing gas produced by decaying uranium
1896
Antoine Becquerel discovers the radioactivity of uranium
1896
Pieter Zeeman studies the splitting of sodium D lines when sodium is held in a flame between strong magnetic poles
1897
Joseph Thomson discovers the electron
1898
William Ramsay and Morris Travers discover neon, krypton, and xenon
1898
Marie Curie and Pierre Curie isolate and study radium and polonium
1899
Ernest Rutherford discovers that uranium radiation is composed of positively charged alpha particles and negatively charged beta articles
1900
Paul Villard discovers gamma-rays while studying uranium decay
1900
Johannes Rydberg refines the expression for observed hydrogen line wavelengths
1900
Max Planck states his quantum hypothesis and blackbody radiation law
1902
Philipp Lenard observes that maximum photoelectron energies are independent of illuminating intensity but depend on frequency
1902
Theodor Svedberg suggests that fluctuations in molecular bombardment cause the Brownian motion
1905
Albert Einstein explains the photoelectric effect
1906
Charles Barkla discovers that each element has a characteristic X-ray and that the degree of penetration of these X-rays is related to the atomic weight of the element
1909
Hans Geiger and Ernest Marsden discover large angle deflections of alpha particles by thin metal foils
1909
Ernest Rutherford and Thomas Royds demonstrate that alpha particles are doubly ionized helium atoms
1911
Ernest Rutherford explains the Geiger-Marsden experiment by invoking a nuclear atom model and derives the Rutherford cross section
1912
Max von Laue suggests using lattice solids to diffract X-rays
1912
Walter Friedrich and Paul Knipping diffract X-rays in zinc blende
1913
William Bragg and Lawrence Bragg work out the Bragg condition for strong X-ray reflection
1913
Henry Moseley shows that nuclear charge is the real basis for numbering the elements
1913
Niels Bohr presents his quantum model of the atom
1913
Robert Millikan measures the fundamental unit of electric charge
1913
Johannes Stark demonstrates that strong electric fields will split the Balmer spectral line series of hydrogen
1914
James Franck and Gustav Hertz observe atomic excitation
1914
Ernest Rutherford suggests that the positively charged atomic nucleus contains protons
1915
Arnold Sommerfeld develops a modified Bohr atomic model with elliptic orbits to explain relativistic fine structure
1916
Gilbert Lewis and Irving Langmuir formulate an electron shell model of chemical bonding
1917
Albert Einstein introduces the idea of stimulated radiation emission
1921
Alfred Landé introduces the Lande g-factor
1922
Arthur Compton studies X-ray photon scattering by electrons
1922
Otto Stern and Walter Gerlach show ``space quantization''
1923
Louis de Broglie suggests that electrons may have wavelike properties
1924
Wolfgang Pauli states the quantum exclusion principle
1924
John Lennard-Jones proposes a semiempirical interatomic force law
1924
Satyendra Bose and Albert Einstein introduce Bose-Einstein statistics
1925
George Uhlenbeck and Samuel Goudsmit postulate electron spin
1925
Pierre Auger discovers the Auger autoionization process
1925
Werner Heisenberg, Max Born, and Pascual Jordan formulate quantum matrix mechanics
1926
Erwin Schrödinger states his nonrelativistic quantum wave equation and formulates quantum wave mechanics
1926
Erwin Schrödinger proves that the wave and matrix formulations of quantum theory are mathematically equivalent
1926
Oskar Klein and Walter Gordon state their relativistic quantum wave equation
1926
Enrico Fermi discovers the spin-statistics connection
1926
Paul Dirac introduces Fermi-Dirac statistics
1927
Clinton Davission, Lester Germer, and George Thomson confirm the wavelike nature of electrons
1927
Werner Heisenberg states the quantum uncertainty principle
1927
Max Born interprets the probabilistic nature of wavefunctions
1928
Chandrasekhara Raman studies optical photon scattering by electrons
1928
Paul Dirac states his relativistic electron quantum wave equation
1928
Charles G. Darwin and Walter Gordon solve the Dirac equation for a Coulomb potential
1929
Oskar Klein discovers the Klein paradox
1929
Oskar Klein and Y. Nishina derive the Klein-Nishina cross section for high energy photon scattering by electrons
1929
N.F. Mott derives the Mott cross section for the Coulomb scattering of relativistic electrons
1930
Paul Dirac introduces electron hole theory
1930
Erwin Schrödinger predicts the zitterbewegung motion
1930
Fritz London explains van der Waals forces as due to the interacting fluctuating dipole moments between molecules
1931
John Lennard-Jones proposes the Lennard-Jones interatomic potential
1931
Irčne Joliot-Curie and Frédéric Joliot-Curie observe but misinterpret neutron scattering in parafin
1931
Wolfgang Pauli puts forth the neutrino hypothesis to explain the apparent violation of energy conservation in beta decay
1931
Linus Pauling discovers resonance bonding and uses it to explain the high stability of symmetric planar molecules
1931
Paul Dirac shows that charge conservation can be explained if magnetic monopoles exist
1931
Harold Urey discovers deuterium using evaporation concentration techniques and spectroscopy
1932
John Cockcroft and Thomas Walton split lithium and boron nuclei using proton bombardment
1932
James Chadwick discovers the neutron
1932
Werner Heisenberg presents the proton-neutron model of the nucleus and uses it to explain isotopes
1932
Carl Anderson discovers the positron
1933
Max Delbrück suggests that quantum effects will cause photons to be scattered by an external electric field
1934
Irčne Joliot-Curie and Frédéric Joliot-Curie bombard aluminum atoms with alpha particles to create artificially radioactive phosporus-30
1934
Leo Szilard realizes that nuclear chain reactions may be possible
1934
Enrico Fermi formulates his theory of beta decay
1934
Lev Landau tells Edward Teller that nonlinear molecules may have vibrational modes which remove the degeneracy of an orbitally degenerate state
1934
Enrico Fermi suggests bombarding uranium atoms with neutrons to make a 93 proton element
1934
Pavel Cerenkov reports that light is emitted by relativistic particles traveling in a nonscintillating liquid
1935
Hideki Yukawa presents a theory of strong interactions and predicts mesons
1935
Albert Einstein, Boris Podolsky, and Nathan Rosen put forth the EPR paradox
1935
Niels Bohr presents his analysis of the EPR paradox
1936
Eugene Wigner develops the theory of neutron absorption by atomic nuclei
1936
Hans Jahn and Edward Teller present their systematic study of the symmetry types for which the Jahn-Teller effect is expeced
1937
H. Hellmann finds the Hellmann-Feynman theorem
1937
Seth Neddermeyer, Carl Anderson, J.C. Street, and E.C. Stevenson discover muons using cloud chamber measurements of cosmic rays
1939
Richard Feynman finds the Hellmann-Feynman theorem
1939
Otto Hahn and Fritz Strassman bombard uranium salts with thermal neutrons and discover barium among the reaction products
1939
Lise Meitner and Otto Frisch determine that nuclear fission is taking place in the Hahn-Strassman experiments
1942
Enrico Fermi makes the first controlled nuclear chain reaction
1942
Ernst Stückelberg introduces the propagator to positron theory and interprets positrons as negative energy electrons moving bacwards through spacetime
1943
Sin-Itiro Tomonaga publishes his paper on the basic physical principles of quantum electrodynamics
1947
Willis Lamb and Robert Retheford measure the Lamb-Retheford shift
1947
Cecil Powell, C.M.G. Lattes, and G.P.S. Occhialini discover the pi-meson by studying cosmic ray tracks
1947
Richard Feynman presents his propagator approach to quantum electrodynamics
1948
Hendrik Casimir predicts a rudimentary attractive Casimir force on a parallel plate capacitor
1951
Martin Deutsch discovers positronium
1953
R. Wilson observes Delbrück scattering of 1.33 MeV gamma-rays by the electric fields of lead nuclei
1954
Chen Yang and Robert Mills investigate a theory of hadronic isospin by demanding local gauge invariance under isotopic spin space rotations---first non-Abelian gauge theory
1955
Owen Chamberlain, Emilio Segrč, Clyde Wiegand, and Thomas Ypsilantis discover the antiproton
1956
Frederick Reines and Clyde Cowan detect antineutrinos
1956
Chen Yang and Tsung Lee propose parity violation by the weak force
1956
Chien Shiung Wu discovers parity violation by the weak force in decaying cobalt
1957
Gerhart Lüders proves the CPT theorem
1957
Richard Feynman, Murray Gell-Mann, Robert Marshak, and Ennackel Sudarshan propose a V-A Lagrangian for weak interactions
1958
Marcus Sparnaay experimentally confirms the Casimir effect
1959
Yakir Aharonov and David Bohm predict the Aharonov-Bohm effect
1960
R.G. Chambers experimentally confirms the Aharonov-Bohm effect
1961
Murray Gell-Mann and Yuval Ne'eman discover the Eightfold Way patterns---SU(3) group
1961
Jeffery Goldstone considers the breaking of global phase symmetry
1962
Leon Lederman shows that the electron neutrino is distinct from the muon neutrino
1963
Murray Gell-Mann and George Zweig propose the quark/aces model
1964
Peter Higgs considers the breaking of local phase symmetry
1964
J.S. Bell shows that all local hidden variable theories must satisfy Bell's inequality
1964
Val Fitch and James Cronin observe CP violation by the weak force in the decay of K mesons
1967
Steven Weinberg puts forth his electroweak model of leptons
1969
J.C. Clauser, M. Horne, A. Shimony, and R. Holt propose a polarization correlation test of Bell's inequality
1970 
Sheldon Glashow, John Iliopoulos, and Luciano Maiani propose the charm quark
1971
Gerard 't Hooft shows that the Glashow-Salam-Weinberg electroweak model can be renormalized
1972
S. Freedman and J.C. Clauser perform the first polarization correlation test of Bell's inequality
1973
David Politzer proposes the asymptotic freedom of quarks
1974
Burton Richter and Samuel Ting discover the psi meson implying the existence of the charm quark
1975
Martin Perl discovers the tauon
1977
S.W. Herb finds the upsilon resonance implying the existence of the beauty quark
1982
A. Aspect, J. Dalibard, and G. Roger perform a polarization correlation test of Bell's inequality that rules out conspiratorial polarizer communication
1983
Carlo Rubbia, Simon van der Meer, and the CERN UA-1 collaboration find the Wpm and Z0 intermediate vector bosons
1989
The Z0 intermediate vector boson resonance width indicates three quark-lepton generations