The
Royal Swedish Academy of Sciences has decided to award the Nobel Prize in
Physics 2017 with one half to Rainer Weiss, the other half jointly to Barry C. Barish
and Kip S.
Thorne "for decisive contributions to the LIGO detector and the
observation of gravitational waves"
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RAINER
WEISS
Born 1932 in Berlin, Germany.
Ph.D. 1962 from Massachusetts Institute of Technology, MIT, Cambridge, MA,
USA. Professor of Physics, Massachusetts Institute of Technology, MIT,
Cambridge, MA, USA.
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BARRY
C. BARISH
Born 1936 in Omaha, NE, USA.
Ph.D. 1962 from University of California, Berkeley, CA, USA. Linde Professor
of Physics, California Institute of Technology, Pasadena, CA, USA
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KIP
S. THORNE
Born 1940 in Logan, UT, USA.
Ph.D. 1965 from Princeton University, NJ, USA. Feynman Professor of
Theoretical Physics, California Institute of Technology, Pasadena, CA, USA
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gknowledge4u.blogspot.in
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Gravitational waves finally
captured
On
14 September 2015, the universe's gravitational waves were observed for the
very first time. The waves, which were predicted by Albert Einstein a hundred
years ago, came from a collision between two black holes. It took 1.3 billion
years for the waves to arrive at the LIGO detector in the USA.
The
signal was extremely weak when it reached Earth, but is already promising a
revolution in astrophysics. Gravitational waves are an entirely new way of
observing the most violent events in space and testing the limits of our
knowledge.
LIGO,
the Laser Interferometer Gravitational-Wave Observatory, is a collaborative
project with over one thousand researchers from more than twenty countries.
Together, they have realised a vision that is almost fifty years old. The 2017
Nobel Laureates have, with their enthusiasm and determination, each been
invaluable to the success of LIGO. Pioneers Rainer Weiss and Kip
S. Thorne, together with Barry C. Barish, the scientist and leader who
brought the project to completion, ensured that four decades of effort led to
gravitational waves finally being observed.
In
the mid-1970s, Rainer Weiss had already analysed possible sources of background
noise that would disturb measurements, and had also designed a detector, a
laser-based interferometer, which would overcome this noise. Early on, both Kip
Thorne and Rainer Weiss were firmly convinced that gravitational waves could be
detected and bring about a revolution in our knowledge of the universe.
Gravitational
waves spread at the speed of light, filling the universe, as Albert Einstein
described in his general theory of relativity. They are always created when a
mass accelerates, like when an ice-skater pirouettes or a pair of black holes
rotate around each other. Einstein was convinced it would never be possible to
measure them. The LIGO project's achievement was using a pair of gigantic laser
interferometers to measure a change thousands of times smaller than an atomic
nucleus, as the gravitational wave passed the Earth.
So
far all sorts of electromagnetic radiation and particles, such as cosmic rays
or neutrinos, have been used to explore the universe. However, gravitational
waves are direct testimony to disruptions in spacetime itself. This is
something completely new and different, opening up unseen worlds. A wealth of
discoveries awaits those who succeed in capturing the waves and interpreting
their message.
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