Theodor Wolfgang Hänsch (b. 30 October 1941 in Heidelberg, Germany) is a German physicist. He received one fourth of the 2005 Nobel Prize in Physics for "contributions to the development of laser-based precision spectroscopy, including the optical frequency comb technique", sharing the prize with John L. Hall and Roy J. Glauber.
Hänsch is Director of the Max-Planck-Institut für Quantenoptik (quantum optics) and Professor of experimental physics and laser spectroscopy at the Ludwig-Maximilians University in Munich, Bavaria, Germany.
Hänsch gained his Diplom and doctoral degree from Ruprecht-Karls-Universität Heidelberg in 1960s. Subsequently, he became a professor at Stanford University, California from 1975 to 1986. He was awarded the Comstock Prize in Physics from the National Academy of Sciences in 1983. In 1986, he received the Albert A. Michelson Medal from the Franklin Institute. In the same year Hänsch returned to Germany to head the Max-Planck-Institut für Quantenoptik. In 1989, he received the Gottfried Wilhelm Leibniz Prize of the Deutsche Forschungsgemeinschaft, which is the highest honour awarded in German research. In 2005, he also received the Otto Hahn Award of the City of Frankfurt am Main, the Society of German Chemists and the German Physical Society. In that same year, the Optical Society of America awarded him the Frederic Ives Medal and the status of honorary member in 2008.
One of his students, Carl E. Wieman, received the Nobel Prize in Physics in 2001.
In 1970 he invented a new type of laser which generated light pulses with an extremely high spectral
resolution (i.e. all the photons emitted from the laser had nearly the
same energy, to a precision of 1 part in a million). Using this device
he succeeded to measure the transition frequency of the Balmer line of atomic hydrogen
with a much higher precision than before. During the late 1990s, he and
his coworkers developed a new method to measure the frequency of laser
light to an even higher precision, using a device called the optical
frequency comb generator. This invention was then used to measure the Lyman
line of atomic hydrogen to an extraordinary precision of 1 part in a
hundred trillion. At such a high precision, it became possible to search
for possible changes in the fundamental physical constants of the universe over time. For these achievements he became co-recipient of the Nobel Prize in Physics for 2005.
The Nobel Prize was awarded to Professor Hänsch in recognition for
work that he did at the end of the 1990s at the Max Planck Institute in
Garching, near Munich, Germany. He developed an optical "frequency comb
synthesiser", which makes it possible, for the first time, to measure
with extreme precision the number of light oscillations per second.
These optical frequency measurements can be millions of times more
precise than previous spectroscopic determinations of the wavelength of
light.
The work in Garching was motivated by experiments on the very precise
laser spectroscopy of the hydrogen atom. This atom has a particularly
simple structure. By precisely determining its spectral line, scientists
were able to draw conclusions about how valid our fundamental physical
constants are - if, for example, they change slowly with time. By the
end of the 1980s, the laser spectroscopy of hydrogen had reached the
maximum precision allowed by interferometric measurements of optical
wavelengths.
The researchers at the Max Planck Institute of Quantum Optics
thus speculated about new methods, and developed the optical frequency
comb synthesizer. Its name comes from the fact that it generates a light
spectrum out of what are originally single-colour, ultrashort pulses of
light. This spectrum is made of hundreds of thousands of sharp spectral
lines with a constant frequency interval.
Such a frequency comb is similar to a ruler. When the frequency of a
particular radiation is determined, it can be compared to the extremely
acute comb spectral lines, until one is found that "fits". In 1998,
Professor Hänsch received a Philip Morris Research Prize for the development of this "measurement device".
One of the first applications of this new kind of light source was to
determine the frequency of the very narrow ultraviolet hydrogen 1S-2S
two-photon transition. Since then, the frequency has been determined
with a precision of 15 decimal places.
The frequency comb now serves as the basis for optical frequency
measurements in large numbers of laboratories worldwide. Since 2002, the
company Menlo Systems, in whose foundation the Max Planck Institute in
Garching played a role, has been delivering commercial frequency comb
synthesizers to laboratories all over the world.
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