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Leonard Susskind (born May 20, 1940)^{[2]}^{[3]} is the Felix Bloch professor of Theoretical physics at Stanford University, and director of the Stanford Institute for Theoretical Physics. His research interests include string theory, quantum field theory, quantum statistical mechanics and quantum cosmology.^{[1]} He is a member of the National Academy of Sciences of the US,^{[4]} and the American Academy of Arts and Sciences,^{[5]} an associate member of the faculty of Canada's Perimeter Institute for Theoretical Physics,^{[6]} and a distinguished professor of the Korea Institute for Advanced Study.^{[7]}
Susskind is widely regarded as one of the fathers of string theory,^{[8]} having, with Yoichiro Nambu and Holger Bech Nielsen, independently introduced the idea that particles could in fact be states of excitation of a relativistic string.^{[9]} He was the first to introduce the idea of the string theory landscape in 2003.^{[10]}^{[11]}
Susskind was awarded the 1998 J. J. Sakurai Prize.^{[12]}
Leonard Susskind was born to a Jewish family from the South Bronx section of New York City,^{[13]} he now resides in Palo Alto, California. He began working as a plumber at the age of 16, taking over from his father who had become ill.^{[13]} Later, he enrolled in the City College of New York as an engineering student, graduating with a B.S. in physics in 1962.^{[5]} In an interview in the Los Angeles Times, Susskind recalls the moment he discussed with his father this change in career path: "When I told my father I wanted to be a physicist, he said: ‘Hell no, you ain’t going to work in a drug store.’ I said, "No. Not a pharmacist." I said, ‘Like Einstein.’ He poked me in the chest with a piece of plumbing pipe. ‘You ain’t going to be no engineer’, he said. ‘You’re going to be Einstein.’"^{[13]} Susskind then studied at Cornell University under Peter A. Carruthers where he earned his Ph.D. in 1965. He has been married twice, first in 1960,^{[5]} and has four children.
Susskind was an assistant professor of physics, then an associate professor at Yeshiva University (1966–1970), after which he went for a year to the University of Tel Aviv (1971–72), returning to Yeshiva to become a professor of physics (1970–1979). Since 1979 he has been professor of physics at Stanford University,^{[1]} and since 2000 has held the Felix Bloch professorship of physics.
Susskind was awarded the 1998 J. J. Sakurai Prize for his "pioneering contributions to hadronic string models, lattice gauge theories, quantum chromodynamics, and dynamical symmetry breaking". Susskind's hallmark, according to colleagues, has been the application of "brilliant imagination and originality to the theoretical study of the nature of the elementary particles and forces that make up the physical world".^{[12]}
In 2007, Susskind joined the faculty of Perimeter Institute for Theoretical Physics in Waterloo, Ontario, Canada, as an associate member. He has been elected to the National Academy of Sciences and the American Academy of Arts and Sciences. He is also a distinguished professor at Korea Institute for Advanced Study.^{[14]}
Susskind was one of at least three physicists who independently discovered during or around 1970 that the Veneziano dual resonance model of strong interactions could be described by a quantum mechanical model of strings,^{[15]} and was the first to propose the idea of the string theory landscape. Susskind has also made contributions in the following areas of physics:
Susskind is the author of several popular science books.
The Cosmic Landscape: String Theory and the Illusion of Intelligent Design is Susskind's first popular science book, published by Little, Brown and Company on December 12, 2005.^{[24]} It is Susskind's attempt to bring his idea of the anthropic landscape of string theory to the general public. In the book, Susskind describes how the string theory landscape was an almost inevitable consequence of several factors, one of which was Steven Weinberg's prediction of the cosmological constant in 1987. The question addressed here is why our universe is fine-tuned for our existence. Susskind explains that Weinberg calculated that if the cosmological constant was just a little different, our universe would cease to exist.
The Black Hole War: My Battle with Stephen Hawking to Make the World Safe for Quantum Mechanics is Susskind's second popular science book, published by Little, Brown, and Company on July 7, 2008.^{[25]} The book is his most famous work and explains what he thinks would happen to the information and matter stored in a black hole when it evaporates. The book sparked from a debate that started in 1981, when there was a meeting of physicists to try to decode some of the mysteries about how particles of particular elemental compounds function. During this discussion Stephen Hawking stated that the information inside a black hole is lost forever as the black hole evaporates. It took 28 years for Leonard Susskind to formulate his theory that would prove Hawking wrong. He then published his theory in his book, The Black Hole War. Like The Cosmic Landscape, The Black Hole War is aimed at the lay reader. He writes: "The real tools for understanding the quantum universe are abstract mathematics: infinite dimensional Hilbert spaces, projection operators, unitary matrices and a lot of other advanced principles that take a few years to learn. But let's see how we do in just a few pages."
Susskind is currently co-authoring a series of companion books to his lecture series The Theoretical Minimum. The first of these, The Theoretical Minimum: What You Need to Know to Start Doing Physics,^{[26]} was published in 2013 and presents the modern formulations of classical mechanics. The second of these, Quantum Mechanics: The Theoretical Minimum,^{[27]} was published in February 2014. The next book is expected to focus on special relativity.
Susskind teaches a series of Stanford Continuing Studies courses about modern physics referred to as The Theoretical Minimum. These lectures later formed the basis for the books of the same name.^{[28]} The goal of the courses is to teach the basic but rigorous theoretical foundations required to study certain areas of physics. The sequence covers classical mechanics, relativity, quantum mechanics, statistical mechanics, and cosmology, including the physics of black holes.^{[29]}
These courses are available on the The Theoretical Minimum website, on iTunes, and on YouTube. The courses are intended for the mathematically literate^{[30]} public as well as physical science/mathematics students. Susskind aims the courses at people with prior exposure to algebra, calculus,^{[31]} vectors, differential calculus, integrals, and perhaps differential operators, matrices, and linear equations. Homework and study outside of class is otherwise unnecessary. Susskind explains most of the mathematics used, which form the basis of the lectures.
The Smolin-Susskind debate refers to the series of intense postings in 2004 between
The insistence on unitarity in the presence of black holes led 't Hooft (1993) and Susskind (1995b) to embrace a more radical, holographic interpretation of ...
The courses are specifically aimed at people who know, or once knew, a bit of algebra and calculus, but are more or less beginners.
Quantum gravity, Spacetime, M-theory, Supersymmetry, Quantum field theory
Long Island, Queens, Brooklyn, Philadelphia, Staten Island
New York City, United States, American Civil War, Hawaii, Western United States
University of California, Berkeley, Brown University, Silicon Valley, California Institute of Technology, Duke University
Quantum mechanics, Electromagnetism, Energy, Astronomy, Thermodynamics
String theory, Quantum gravity, Nuclear physics, M-theory, Spacetime
String theory, Quantum gravity, M-theory, Entropy, Space
String theory, ArXiv, Leonard Susskind, Quantum gravity, AdS/CFT correspondence
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