Murray Gell-Mann

Murray Gell-Mann (15 September 1929 – 24 May 2019) was an American theoretical physicist who played a preeminent role in the development of the theory of elementary particles, for which he received the 1969 Nobel Prize in Physics.

Gell-Mann introduced the concept of quarks as the fundamental building blocks of the strongly interacting particles, and the renormalization group as a foundational element of quantum field theory and statistical mechanics. He played key roles in developing the concept of chirality in the theory of the weak interactions and spontaneous chiral symmetry breaking in the strong interactions, which controls the physics of the light mesons. In the 1970s he was a co-inventor of quantum chromodynamics (QCD) which explains the confinement of quarks in mesons and baryons and forms a large part of the Standard Model of elementary particles and forces.

• Possibly we will find an elegant model, in agreement with observation, that yields the pattern of lepton masses as well as the pattern of quark bare masses and even relates hadrons and leptons. This is our dream; touch us!
  • General status: summary and outlook 333–355. CERN, Geneva, Switzerland (1983). (quote frem p. 336)

• Today the network of relationships linking the human race to itself and to the rest of the biosphere is so complex that all aspects affect all others to an extraordinary degree. Someone should be studying the whole system, however crudely that has to be done, because no gluing together of partial studies of a complex nonlinear system can give a good idea of the behaviour of the whole.
  • Murray Gell-Mann in ISSS The Primer Project International Society for the Systems Sciences (ISSS) seminar (12 October - 10 November 1997).

• I thought of killing myself but soon decided that I could always try MIT and then kill myself later if it was that bad but that I couldn't commit suicide and then try MIT afterwards. The two operations, suicide and going to MIT, don't commute...
  • "The Making of a Physicist : A Talk with Murray Gell-Mann" at Edge.org (2003).

• Just because things get a little dingy at the subatomic level doesn't mean all bets are off.
  • Attributed to Murray Gell-Mann by Penn Jillette, Penn Radio (14 February 2007).

• Three principles — the conformability of nature to herself, the applicability of the criterion of simplicity, and the "unreasonable effectiveness" of certain parts of mathematics in describing physical reality — are thus consequences of the underlying law of the elementary particles and their interactions. Those three principles need not be assumed as separate metaphysical postulates. Instead, they are emergent properties of the fundamental laws of physics.
  • TED talk on beauty and truth in physics —video timecode 14m28s (March 2007).

• You don't need something more to get something more. That's what emergence means. Life can emerge from physics and chemistry plus a lot of accidents. The human mind can arise from neurobiology and a lot of accidents, the way the chemical bond arises from physics and certain accidents. Doesn't diminish the importance of these subjects to know they follow from more fundamental things plus accidents.
  • TED talk on beauty and truth in physics — video TC 14m48s (March 2007).

• If I have seen further than others, it is because I am surrounded by dwarfs.
  • As quoted in "Wilson vs Watson: The blessing of great enemies" by Amanda Gefter in New Scientist (10 September 2009); this is a play upon the famous statement by Isaac Newton: "If I have seen further it is only by standing on the shoulders of giants."

• Niels Bohr brain-washed a whole generation of physicists into believing that the problem had been solved fifty years ago [Gell-Mann's comment on the Copenhagen interpretation]
  • In The Nature of the Physical Universe, the 1976 Nobel Conference, (1979, p. 29)

• While many questions about quantum mechanics are still not fully resolved, there is no point in introducing needless mystification where in fact no problem exists. Yet a great deal of recent writing about quantum mechanics has done just that.
  • Ch. 12 : Quantum Mechanics and Flapdoodle, p. 167.

• The principal distortion disseminated ... is the implication, or even the explicit claim, that measuring the polarization, circular or plane, of one of the [EPRB] photons somehow affects the other photon. In fact, the measurement does not cause any physical effect to propagate from one photon to the other. ...If on one branch of history, the plane polarization of one photon is measured and thereby specified with certainty, then on the same branch of history the circular polarization of the other photon is also specified with certainty. On a different branch of history the circular polarization of one of the photons may be measured, in which case the circular polarization of both photons is specified with certainty. On each branch, the situation is like that of Bertlmann's socks, described by John Bell... Bertlmann... always wears one pink and one green sock. If you see just one... you know immediately the other... Yet no signal is propogated... Likewise no signal passes from one photon to the other in the experiment that confirms quantum mechanics. No action at a distance takes place.
  • Ch. 12 : Quantum Mechanics and Flapdoodle, p. 172.

• The false report that measuring one of the photons immediately affects the other leads to all sorts of unfortunate conclusions. ...the alleged effect ...would violate the requirement of relativity theory that no signal... can travel faster than the speed of light. If it were to do so, it would appear to observers in some states of motion that the signal were traveling backward in time.
  • Ch. 12 : Quantum Mechanics and Flapdoodle, pp. 172-173 see EPR paradox.

• I had barely sat down when he began to tell me... that science writers were "ignoramuses" and a "terrible breed" who invariably got things wrong: only scientists were really qualified to present their work to the masses. As time went on, I felt less offended, since it became clear that Gell-Mann held most of his scientific colleagues in contempt as well.
  • John Horgan, The End of Science (1996) p. 212

• One of the things that makes Gell-Mann so insufferable is that he is almost always right.
  • John Horgan, The End of Science (1996) p. 215

• Briefly stated, the Gell-Mann Amnesia effect works as follows. You open the newspaper to an article on some subject you know well. In Murray’s case, physics. In mine, show business. You read the article and see the journalist has absolutely no understanding of either the facts or the issues. Often, the article is so wrong it actually presents the story backward-reversing cause and effect. I call these the “wet streets cause rain” stories. Paper’s full of them. In any case, you read with exasperation or amusement the multiple errors in a story-and then turn the page to national or international affairs, and read with renewed interest as if the rest of the newspaper was somehow more accurate about far-off Palestine than it was about the story you just read. You turn the page, and forget what you know.
  • Michael Crichton, Why Speculate (26 April 2002)

Wikipedia has an article about:

Murray Gell-Mann

• Biography and Bibliographic Resources, from the Department of Energy, Office of Scientific & Technical Information
• Gell-Mann's Home Page at SFI
• TED Talks: Murray Gell-Mann on beauty and truth in physics at TED (2007)
• TED Talks: Murray Gell-Mann on the ancestor of language at TED (2007)
• Murray Gell-Mann Video Interview with the Academy of Achievement (1990)
• Murray Gell-Mann talks quarks (Video)
• Math Genealogy profile