Quantum Theory Timeline

Quantum Theory timeline

At the start of the twentieth century, scientists believed that they understood the most fundamental principles of nature. Atoms were solid building blocks of nature; people trusted Newtonian laws of motion; most of the problems of physics seemed to be solved. However, starting with Einstein's theory of relativity which replaced Newtonian mechanics, scientists gradually realized that their knowledge was far from complete. Of particular interest was the growing field of quantum mechanics, which completely altered the fundamental precepts of physics.

Particles discovered 1898 - 1964:

1900 Max Planck suggests that radiation is quantized (it comes in discrete amounts.)

1905 Albert Einstein, one of the few scientists to take Planck's ideas seriously, proposes a quantum of light (the photon) which behaves like a particle. Einstein's other theories explained the equivalence of mass and energy, the particle-wave duality of photons, the equivalence principle, and special relativity.

1909 Hans Geiger and Ernest Marsden, under the supervision of Ernest Rutherford, scatter alpha particles off a gold foil and observe large angles of scattering, suggesting that atoms have a small, dense, positively charged nucleus.

1911 Ernest Rutherford infers the nucleus as the result of the alpha-scattering experiment performed by Hans Geiger and Ernest Marsden.

1912 Albert Einstein explains the curvature of space-time.

1913 Niels Bohr succeeds in constructing a theory of atomic structure based on quantum ideas.

1919 Ernest Rutherford finds the first evidence for a proton.

1921 James Chadwick and E.S. Bieler conclude that some strong force holds the nucleus together.

1923 Arthur Compton discovers the quantum (particle) nature of x rays, thus confirming photons as particles.

1924 Louis de Broglie proposes that matter has wave properties.

1925 (Jan) Wolfgang Pauli formulates the exclusion principle for electrons in an atom.

1925 (April) Walther Bothe and Hans Geiger demonstrate that energy and mass are conserved in atomic processes.

1926 Erwin Schroedinger develops wave mechanics, which describes the behavior of quantum systems for bosons. Max Born gives a probability interpretation of quantum mechanics. G.N. Lewis proposes the name "photon" for a light quantum.

1927 Certain materials had been observed to emit electrons (beta decay). Since both the atom and the nucleus have discrete energy levels, it is hard to see how electrons produced in transition could have a continuous spectrum (see 1930 for an answer.)

1927 Werner Heisenberg formulates the uncertainty principle: the more you know about a particle's energy, the less you know about the time of the energy (and vice versa.) The same uncertainty applies to momenta and coordinates.

1928 Paul Dirac combines quantum mechanics and special relativity to describe the electron.

1930 Quantum mechanics and special relativity are well established. There are just three fundamental particles: protons, electrons, and photons. Max Born, after learning of the Dirac equation, said, "Physics as we know it will be over in six months."

1930 Wolfgang Pauli suggests the neutrino to explain the continuous electron spectrum for beta decay.

1931 Paul Dirac realizes that the positively-charged particles required by his equation are new objects (he calls them "positrons"). They are exactly like electrons, but positively charged. This is the first example of antiparticles.

1931 James Chadwick discovers the neutron. The mechanisms of nuclear binding and decay become primary problems.

1933-34 Enrico Fermi puts forth a theory of beta decay that introduces the weak interaction. This is the first theory to explicitly use neutrinos and particle flavor changes.

1933-34 Hideki Yukawa combines relativity and quantum theory to describe nuclear interactions by an exchange of new particles (mesons called "pions") between protons and neutrons. From the size of the nucleus, Yukawa concludes that the mass of the conjectured particles (mesons) is about 200 electron masses. This is the beginning of the meson theory of nuclear forces.

1937 A particle of 200 electron masses is discovered in cosmic rays. While at first physicists thought it was Yukawa's pion, it was later discovered to be a muon.

1938 E.C.G. Stuckelberg observes that protons and neutrons do not decay into any combination of electrons, neutrinos, muons, or their antiparticles. The stability of the proton cannot be explained in terms of energy or charge conservation; he proposes that heavy particles are independently conserved.

1941 C. Moller and Abraham Pais introduce the term "nucleon" as a generic term for protons and neutrons.

1946-47 Physicists realize that the cosmic ray particle thought to be Yukawa's meson is instead a "muon," the first particle of the second generation of matter particles to be found. This discovery was completely unexpected -- I.I. Rabi comments "who ordered that?" The term "lepton" is introduced to describe objects that do not interact too strongly (electrons and muons are both leptons).

1947 A meson that does interact strongly is found in cosmic rays, and is determined to be the pion.

1947 Physicists develop procedures to calculate electromagnetic properties of electrons, positrons, and photons. Introduction of Feynman diagrams.

1948 The Berkeley synchro-cyclotron produces the first artificial pions.

1949 Enrico Fermi and C.N. Yang suggest that a pion is a composite structure of a nucleon and an anti-nucleon. This idea of composite particles is quite radical.

1949 Discovery of K⁺ via its decay.

1950 The neutral pion is discovered.

1951 Two new types of particles are discovered in cosmic rays. They are discovered by looking a V-like tracks and reconstructing the electrically-neutral object that must have decayed to produce the two charged objects that left the tracks. The particles were named the lambda⁰ and the K⁰.

1952 Discovery of particle called delta: there were four similar particles (delta⁺⁺, delta⁺, delta^⁰, and delta^-.)

1952 Donald Glaser invents the bubble chamber. The Brookhaven Cosmotron, a 1.3 GeV accelerator, starts operation.

1953 The beginning of a "particle explosion" -- a true proliferation of particles.

1953 - 57 Scattering of electrons off nuclei reveals a charge density distribution inside protons, and even neutrons. Description of this electromagnetic structure of protons and neutrons suggests some kind of internal structure to these objects, though they are still regarded as fundamental particles.

1954 C.N. Yang and Robert Mills develop a new class of theories called "gauge theories." Although not realized at the time, this type of theory now forms the basis of the Standard Model.

1957 Julian Schwinger writes a paper proposing unification of weak and electromagnetic interactions.

1957-59 Julian Schwinger, Sidney Bludman, and Sheldon Glashow, in separate papers, suggest that all weak interactions are mediated by charged heavy bosons, later called W⁺ and W^-. Actually, it was Yukawa who first discussed boson exchange twenty years earlier, but he proposed the pion as the mediator of the weak force.

1961 As the number of known particles keep increasing, a mathematical classification scheme to organize the particles (the group SU(3)) helps physicists recognize patterns of particle types.

1962 Experiments verify that there are two distinct types of neutrinos (electron and muon neutrinos). This was earlier inferred from theoretical considerations.

Return to the main timeline

1900	Max Planck suggests that radiation is quantized (it comes in discrete amounts.)
1905	Albert Einstein, one of the few scientists to take Planck's ideas seriously, proposes a quantum of light (the photon) which behaves like a particle. Einstein's other theories explained the equivalence of mass and energy, the particle-wave duality of photons, the equivalence principle, and special relativity.
1909	Hans Geiger and Ernest Marsden, under the supervision of Ernest Rutherford, scatter alpha particles off a gold foil and observe large angles of scattering, suggesting that atoms have a small, dense, positively charged nucleus.
1911	Ernest Rutherford infers the nucleus as the result of the alpha-scattering experiment performed by Hans Geiger and Ernest Marsden.
1912	Albert Einstein explains the curvature of space-time.
1913	Niels Bohr succeeds in constructing a theory of atomic structure based on quantum ideas.
1919	Ernest Rutherford finds the first evidence for a proton.
1921	James Chadwick and E.S. Bieler conclude that some strong force holds the nucleus together.
1923	Arthur Compton discovers the quantum (particle) nature of x rays, thus confirming photons as particles.
1924	Louis de Broglie proposes that matter has wave properties.
1925 (Jan)	Wolfgang Pauli formulates the exclusion principle for electrons in an atom.
1925 (April)	Walther Bothe and Hans Geiger demonstrate that energy and mass are conserved in atomic processes.
1926	Erwin Schroedinger develops wave mechanics, which describes the behavior of quantum systems for bosons. Max Born gives a probability interpretation of quantum mechanics. G.N. Lewis proposes the name "photon" for a light quantum.
1927	Certain materials had been observed to emit electrons (beta decay). Since both the atom and the nucleus have discrete energy levels, it is hard to see how electrons produced in transition could have a continuous spectrum (see 1930 for an answer.)
1927	Werner Heisenberg formulates the uncertainty principle: the more you know about a particle's energy, the less you know about the time of the energy (and vice versa.) The same uncertainty applies to momenta and coordinates.
1928	Paul Dirac combines quantum mechanics and special relativity to describe the electron.
1930	Quantum mechanics and special relativity are well established. There are just three fundamental particles: protons, electrons, and photons. Max Born, after learning of the Dirac equation, said, "Physics as we know it will be over in six months."
1930	Wolfgang Pauli suggests the neutrino to explain the continuous electron spectrum for beta decay.
1931	Paul Dirac realizes that the positively-charged particles required by his equation are new objects (he calls them "positrons"). They are exactly like electrons, but positively charged. This is the first example of antiparticles.
1931	James Chadwick discovers the neutron. The mechanisms of nuclear binding and decay become primary problems.
1933-34	Enrico Fermi puts forth a theory of beta decay that introduces the weak interaction. This is the first theory to explicitly use neutrinos and particle flavor changes.
1933-34	Hideki Yukawa combines relativity and quantum theory to describe nuclear interactions by an exchange of new particles (mesons called "pions") between protons and neutrons. From the size of the nucleus, Yukawa concludes that the mass of the conjectured particles (mesons) is about 200 electron masses. This is the beginning of the meson theory of nuclear forces.
1937	A particle of 200 electron masses is discovered in cosmic rays. While at first physicists thought it was Yukawa's pion, it was later discovered to be a muon.
1938	E.C.G. Stuckelberg observes that protons and neutrons do not decay into any combination of electrons, neutrinos, muons, or their antiparticles. The stability of the proton cannot be explained in terms of energy or charge conservation; he proposes that heavy particles are independently conserved.
1941	C. Moller and Abraham Pais introduce the term "nucleon" as a generic term for protons and neutrons.
1946-47	Physicists realize that the cosmic ray particle thought to be Yukawa's meson is instead a "muon," the first particle of the second generation of matter particles to be found. This discovery was completely unexpected -- I.I. Rabi comments "who ordered that?" The term "lepton" is introduced to describe objects that do not interact too strongly (electrons and muons are both leptons).
1947	A meson that does interact strongly is found in cosmic rays, and is determined to be the pion.
1947	Physicists develop procedures to calculate electromagnetic properties of electrons, positrons, and photons. Introduction of Feynman diagrams.
1948	The Berkeley synchro-cyclotron produces the first artificial pions.
1949	Enrico Fermi and C.N. Yang suggest that a pion is a composite structure of a nucleon and an anti-nucleon. This idea of composite particles is quite radical.
1949	Discovery of K⁺ via its decay.
1950	The neutral pion is discovered.
1951	Two new types of particles are discovered in cosmic rays. They are discovered by looking a V-like tracks and reconstructing the electrically-neutral object that must have decayed to produce the two charged objects that left the tracks. The particles were named the lambda⁰ and the K⁰.
1952	Discovery of particle called delta: there were four similar particles (delta⁺⁺, delta⁺, delta^⁰, and delta^-.)
1952	Donald Glaser invents the bubble chamber. The Brookhaven Cosmotron, a 1.3 GeV accelerator, starts operation.
1953	The beginning of a "particle explosion" -- a true proliferation of particles.
1953 - 57	Scattering of electrons off nuclei reveals a charge density distribution inside protons, and even neutrons. Description of this electromagnetic structure of protons and neutrons suggests some kind of internal structure to these objects, though they are still regarded as fundamental particles.
1954	C.N. Yang and Robert Mills develop a new class of theories called "gauge theories." Although not realized at the time, this type of theory now forms the basis of the Standard Model.
1957	Julian Schwinger writes a paper proposing unification of weak and electromagnetic interactions.
1957-59	Julian Schwinger, Sidney Bludman, and Sheldon Glashow, in separate papers, suggest that all weak interactions are mediated by charged heavy bosons, later called W⁺ and W^-. Actually, it was Yukawa who first discussed boson exchange twenty years earlier, but he proposed the pion as the mediator of the weak force.
1961	As the number of known particles keep increasing, a mathematical classification scheme to organize the particles (the group SU(3)) helps physicists recognize patterns of particle types.
1962	Experiments verify that there are two distinct types of neutrinos (electron and muon neutrinos). This was earlier inferred from theoretical considerations.