The Columbia University Physics Department includes approximately 40 faculty members teaching and conducting research in the areas of astrophysics, high energy nuclear physics, high energy particle physics, atomic-molecular-optical physics, condensed matter physics, and theoretical physics.
This research is conducted in Pupin Hall and the Shapiro Center for Engineering and Physical Sciences Research (CEPSR), both on the university's Morningside Heights campus, Nevis Labs upstate, and at a number of other affiliated institutions. The department is connected with research conducted at Brookhaven National Laboratories and at CERN.
Columbia has approximately 20 undergraduate physics majors and is home to about 100 graduate students.
History
The roots of graduate physics can be traced back to the opening of the School of Mines in 1864 although the department was only formally established in 1892. In 1899 the American Physical Society was founded at a meeting at Columbia. Several years later, the Earnest Kempton Adams Fund enabled the department to invite distinguished scientists to the school. Among the distinguished EKA lecturers were Hendrik Lorentz (1905-1906) and Max Planck (1909). During Lorentz's stay at Columbia he wrote one of his most important works, the Theory of Electrons.
By 1931, Pupin Labs was a leading research center. During this time Harold Urey (Nobel laureate in Chemistry) discovered deuterium and George B. Pegram was investigating the phenomena associated with the newly discovered neutron. In 1938, Enrico Fermi escaped fascist Italy after winning the Nobel prize for his work on induced radioactivity. In fact, he took his wife and children with him to Stockholm and immediately emigrated to New York. Shortly after arriving he began working at Columbia. His work on nuclear fission, together with Rabi's work on atomic and molecular physics, ushered in a golden era of fundamental research at the university. One of the country's first cyclotrons was built in the basement of Pupin Hall, where parts of it still remain.
During the war, many microwave techniques were learned that were later used at Columbia for the development of the maser, the microwave precursor to the laser, at to the observation of large nuclear quadrupole moments, which led to the introduction of the unified nuclear model by James Rainwater. In the 1940s theoretical research was focussed on calculations in quantum electrodynamics. In the 1950s, there was a shift towards high-energy physics. During this time Tsung-Dao Lee and his collaborators' work led to the discovery of parity and charge conjugation symmetries in the weak interaction. During these years, a new, more powerful cyclotron was also built at Nevis.
As physicists investigated matter at ever finer scales, higher energy experiments were required. Many of these were done at Nevis and at Brookhaven. Rainwater and Fitch explored the structure of nuclei by observing x-ray transitions in muonic atoms. Richard Garwin and Leon Lederman observed parity nonconservation in pion and muon decay. Lederman, Schwartz, and Steinberger proved that the muon neutrino was distinct from the electron neutrino.
This article uses material from the Wikipedia article Pupin_Laboratories, and is written by contributors.
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