Ali Javan was born in
Tehran to
Iranian Azerbaijani parents from
Tabriz. He attended a school conducted by
Zoroastrians. He graduated from
Alborz High School, and started his university studies at the School of Science at the
University of Tehran for a year. During a visit to New York in 1948, he attended several graduate courses at
Columbia University. He received his Ph.D. in 1954 under his thesis advisor
Charles Townes without having received a bachelor's or master's degree. and his discovery of the stimulated Raman effect showed that a Stokes-shifted Raman transition can produce amplification without requiring a population inversion. The effect was the precursor of a class of effects known as
Lasers Without Inversion, or the LWI effect. He joined
Bell Telephone Laboratories in 1958 shortly after he conceived the working principle of his gas discharge
Helium Neon laser, and subsequently submitted his paper for publication which was reviewed by
Samuel Goudsmit in 1960. Javan's gas laser was the first continuously operating laser. It operated with a very low-energy input of about 25 watts or 50 watts in the first model, compared to thousands of watts required for the
ruby lasers to produce short bursts. In 1966, Ali Javan and
Theodore Maiman split a cash award presented to them by
President Johnson honoring their work. In 1971, he became the director of
Symposium on Laser Physics, which was held on the campus of
University of Isfahan. Another major experiment was his observation of the detuning dip called the Lamb dip while scanning the frequency of a single-mode laser across the Doppler-broadened gain profile. Ali Javan and his colleagues pioneered in stabilizing laser frequencies with techniques utilizing the Lamb dip. In 1964, Javan and Townes devised experiments using lasers to test
special relativity including a variant of the
Michelson-Morley ether drift experiment to study the anisotropy of space. Javan's group repeated the Michelson-Morley experiment with a new order of accuracy by turning their lasers in different directions regarding the earth's motion. Any change in the velocity of light would show up as a change in the frequency of the output beam. The apparatus used was sensitive enough to detect a change as small as 0.03 millimeter per second (compared to the accuracy of 150 millimeters per second attained by
Albert A. Michelson). At MIT in the early 1960s, Ali Javan started a research project aimed at extending microwave frequency-measuring techniques into the infrared. He introduced the concept of an optical antenna of several wavelengths long which enables the near-complete confinement of an incident optical field coupled to it, and forming the antenna in nanoscale. For the first time an antenna was used to receive light and to transmit it to an infinitesimal receiving structure at its tip, observable only with an electron microscope. Using this method Javan developed the first absolutely accurate measurement of the
speed of light. Javan first worked at Massachusetts Institute of Technology as an associate professor of physics in 1961 and has remained Francis Wright Davis Professor Emeritus of physics since 1964. He continued researching into the area of "optical electronics", which envisions scaling electronic elements in such a way that they would be capable of handling frequencies as high as visible optical radiation frequencies. Javan died on September 12, 2016. He is survived by his wife, Marjorie, and by their two daughters, Lila and Maia. ==Honors==