Frank Wilczek

Frank Anthony Wilczek (

Born in Mineola, New York, Wilczek is of Polish and Italian origin.^[1] His grandparents were immigrants who "really did work with their hands", according to Wilczek, but Frank's father took night school classes to educate himself, working as a repairman to support his family.^[7] Wilczek's father became a "self-taught engineer", whose interests in technology and science inspired his son.^[8]

Wilczek was educated in the public schools of

He received his Bachelor of Science in Mathematics and membership in Phi Beta Kappa^[12] at the University of Chicago in 1970. During his last year as a math major at Chicago, he attended a course taught by Peter Freund on group theory in physics, which Wilczek later described as being "basically particle physics", and very influential:^[7]

Peter Freund played a big role in my life, though, because he taught this course on group theory, or symmetry in physics that—he was so enthusiastic, and he really gushed—and it's beautiful material. Still to this day I think the quantum theory of angular momentum is one of the absolute pinnacles of human achievement. Just beautiful.

Wilczek went to Princeton as a mathematics graduate student. After a year and a half, he transferred from mathematics to physics, with David Gross as his thesis advisor.^[7]

He earned a Master of Arts in Mathematics in 1972 and a Ph.D. in physics in 1974, both from Princeton University.^[13]

Personal life

Wilczek met Betsy Devine at Princeton, when both watched the televised 1972 Fisher-Spassky chess matches.^[14] They married in 1973, and together they have two daughters.^[1] His favorite physicist is James Clerk Maxwell.^[15]

Religious views

Wilczek was raised

Wilczek said that "the world embodies beautiful ideas" but "although this may inspire a spiritual interpretation, it does not require one".[19]^[20]

Science outreach and activism

Wilczek is a member of the Scientific Advisory Board for the Future of Life Institute, an organization that works to mitigate existential risks facing humanity, particularly existential risk from advanced artificial intelligence.^[21]

In 2014, Wilczek penned a letter, along with

Wilczek is also a supporter of the Campaign for the Establishment of a United Nations Parliamentary Assembly, an organization which advocates for democratic reform in the United Nations, and the creation of a more accountable international political system.^[23]

Wilczek is on the board for

Wilczek has appeared on an episode of Penn & Teller: Bullshit!, where Penn referred to him as "the smartest person [they have] ever had on the show".

Honors

In 1982, he was awarded a

Wilczek was elected as a member of the National Academy of Sciences in 1990, a member of the American Academy of Arts and Sciences in 1993,^[26][27] and the American Philosophical Society in 2005.^[28]

Wilczek became a foreign member of the

The axion is a hypothetical elementary particle. If axions exist and have low mass within a specific range, they are of interest as a possible component of cold dark matter.

In 1977,

In

In 2012 he proposed the idea of a time crystal.^[49] In 2018, several research teams reported the existence of time crystals.^[50] In 2018 he and Qing-Dong Jiang calculated that the so-called "quantum atmosphere" of materials should theoretically be capable of being probed using existing technology such as diamond probes with nitrogen-vacancy centers.^[51][52]

Current research

• "Pure" particle physics: connections between theoretical ideas and observable phenomena;
• behavior of matter: phase structure of
  quark matter at ultra-high temperature and density; color superconductivity
  ;
• application of particle physics to cosmology;
• application of field theory techniques to condensed matter physics;
• black holes; see e.g the application of the moving mirror model to black holes.^[53]

• 2021
  ISBN 978-0735223790
• 2015 A Beautiful Question: Finding Nature’s Deep Design, Allen Lane,
  ISBN 9781846147012
• 2014 (with
  Huffington Post
  .
• 2008. The Lightness of Being: Mass, Ether, and the Unification of Forces.
  ISBN 978-0-465-00321-1
  .
• 2007. La musica del vuoto. Roma: Di Renzo Editore.
• 2006. Fantastic Realities: 49 Mind Journeys And a Trip to Stockholm. World Scientific.
  ISBN 978-981-256-655-3
  .
• 2002, "On the world's numerical recipe (an ode to physics)", Daedalus 131(1): 142–47.
• 1989 (with
  ISBN 978-0-393-30596-8
  .

Technical

Scholia has a profile for Frank Wilczek (Q107450).

• 1988. Geometric Phases in Physics.
• 1990. Fractional Statistics and Anyon Superconductivity.^[54]

• Wilczek, F.; Gross, D. J. (1973). "Asymptotically Free Gauge Theories. I".
  OSTI 4312175
  .
• Wilczek, F.; Gross, D. J. (1973). "Ultraviolet Behavior of non-Abelian Gauge Theories".
  doi:10.1103/PhysRevLett.30.1343
  .
• Wilczek, F.; Zee, A.; Treiman, S. B. (1974). Scaling Deviations for Neutrino Reactions in Aysmptotically Free Field Theories (PDF) (Report).
  OSTI 4256152
  .
• Wilczek, F.; Zee, A.; Kingsley, R. L.; Treiman, S. B. (1975). "Weak Interaction Models with New Quarks and Right-handed Currents".
  OSTI 4082874
  .
• Wilczek, F. (1978). "Problem of Strong P and T Invariance in the Presence of Instantons".
  doi:10.1103/PhysRevLett.40.279
  .
• Wilczek, F. (1982). "Quantum Mechanics of Fractional Spin Particles".
  S2CID 120702932
  .
• Wilczek, F.; Turner, M. S. (1990). "Inflationary Axion Cosmology".
  PMID 10043128
  .
• Wilczek, F.; Alford, M. G.; Rajagopal, K. (1998). "QCD at finite baryon density: Nucleon droplets and color superconductivity".
  S2CID 2831570
  .
• Wilczek, F. (1998). "Riemann–Einstein structure from volume and gauge symmetry".
  S2CID 10272760
  .
• Wilczek, F.; Fradkin, E. H.; Nayak, C.; Tsvelik, A. (1998). "A Chern–Simons effective field theory for the Pfaffian quantum Hall state".
  S2CID 119036166
  .
• Wilczek, F.; Alford, M. G.; Rajagopal, K. (1999). "Color-flavor locking and chiral symmetry breaking in high density QCD".
  S2CID 6781304
  .
• Wilczek, F. (1999). "Quantum field theory".
  S2CID 279980
  .
• Wilczek, F.; Schafer, T. (1999). "Continuity of quark and hadron matter".
  S2CID 16217372
  .
• Wilczek, F.; Babu, K.S.; Pati, J.C. (2000). "Fermion masses, neutrino oscillations, and proton decay in the light of SuperKamiokande".
  S2CID 14736670
  .
• Wilczek, F.; Linder, E. V.; Good, M.R.R. (2020). "Moving mirror model for quasithermal radiation fields".
  S2CID 213899274
  .

See also

• Coupling unification
• Dark matter
• WIMP
• Quantum number
• Soliton
• Fractional statistics
• Hall effect
• MIT Physics Department

References

1. ^ ^{a b c d} "Frank Wilczek – Autobiography". Nobel Prize.
2. ^ Wilczek, Frank. 2004 Nobel Highlights with Laureates in Physics, David J. Gross, H. David Politzer, Frank Wilczek. Nobel Prize. Event occurs at 0:42 – via YouTube.
3. ^ Wilczek, Frank. A Beautiful Question. Talks at Google. Event occurs at 0:13 – via YouTube.
4. ^ "Frank Wilczek, Herman Feshbach Professor of Physics". Department of Physics, MIT. 2011. Retrieved 2011-06-14.
5. ^ "Frank Wilczek Facts". NobelPrize.org. Stockholm: Nobel Foundation. Retrieved 2020-05-06.
6. ^ Thomas, Burnett (May 11th, 2022). "Dr. Frank Wilczek Receives 2022 Templeton Prize", The Templeton Prize. Retrieved 11 May 2022.
7. ^ ^{a b c} Wilczek, Frank (September 15, 2020). "Oral history interview with Frank Wilczek, 2020 June 4". AIP. Retrieved September 18, 2020. Somewhere between working class and lower middle class. Yeah, lower middle class, I guess I would say. Unlike my grandparents, who really did work with their hands, my father, as I said, was kind of a technician and repairman. He actually got very good at the job and was rising through the ranks.
8. ^ "The Nobel laureate who got hooked on Stockholm". Stockholm University. September 15, 2020. Archived from the original on October 16, 2017. Retrieved September 18, 2020. Frank Wilczek's story starts in Queens, New York, where he grew up in a working-class family with roots in Europe. They were children of the Great Depression from Long Island and had limited access to resources, but that didn't stop them from working to educate themselves. Frank's father was a self-taught engineer and passed his interest in technology and science on to his son.
9. ^ Dreifus, Claudia (December 28, 2009). "Discovering the Mathematical Laws of Nature". The New York Times. Retrieved 22 May 2012.
10. ^ "Noteworthy graduates: Frank Wilczek, Nobel laureate in physics". United Federation of Teachers. December 7, 2018. Retrieved September 24, 2020. As a high school senior, Wilczek was a finalist in the national Science Talent Search. He says his premise about mathematical structures called groups was the best part of his project, posing 'a sensible question for someone to ask at that stage'.
11. ^ "Westinghouse Science Talent Search 1967". Society for Science. Retrieved May 11, 2022.
12. ^ "FRANK WILCZEK CURRICULUM VITAE – PDF". docplayer.net.
13. ^ Frank Anthony Wilczek at the Mathematics Genealogy Project
14. ^ Thompson, Elizabeth A (October 5, 2004). "Wilczek thanks family, country and Mother Nature". MIT News. Retrieved September 21, 2020. 'I noticed that whatever moves Frank called out, the players would do what he said. They'd make the moves he predicted. This happened even when what he called out was different from what others called out', recalled Devine.
15. ^ Wilczek, Frank (2015). A Beautiful Question.
16. ^ Merali, Zeeya (May 11, 2022). "God, Dark Matter and Falling Cats: A Conversation with 2022 Templeton Prize Winner Frank Wilczek". Scientific American. Retrieved June 12, 2022. The use of the word "God" in common culture is very loose. People can mean entirely different things by it. For me, the unifying thread is thinking big: thinking about how the world works, what it is, how it came to be and what all that means for what we should do. I chose to study this partly to fill the void that was left when I realized I could no longer accept the dogmas of the Catholic Church that had meant a lot to me as a teenager.
17. ^ Wang, Amy X. (4 August 2015). "Why Is the World So Beautiful? A Physicist Tries to Answer". Slate Magazine.
18. ^ Wilczek, Frank [@FrankWilczek] (September 8, 2013). "My Wikipedia entry says "agnostic", but "pantheist" is closer to the mark. Spinoza, Beethoven, Walt Whitman, Einstein – good company!" (Tweet) – via Twitter.
19. ^ 'A Beautiful Question', pp. 1–3, 322
20. ^ "A theoretical physicist searches for the design behind nature's beauty". Slate. Retrieved 28 January 2016.
21. ^ Who We Are, Future of Life Institute, 2014, archived from the original on 2014-06-05, retrieved 2014-05-07
22. The Independent (UK)
    . 1 May 2014. Retrieved 28 January 2016.
23. ^ "Overview". Campaign for a UN Parliamentary Assembly. Retrieved 2017-10-27.
24. ^ "Kosciuszko Foundation - American Center of Polish culture - Eminent Scientists of Polish Origin and Ancestry". www.thekf.org. Archived from the original on 2018-05-09. Retrieved 2017-09-18.
25. ^ "Frank Wilczek – MacArthur Foundation". www.macfound.org. Retrieved 2019-01-19.
26. ^ "Frank Wilczek". www.nasonline.org. Retrieved 2020-05-11.
27. ^ "Frank Wilczek". American Academy of Arts & Sciences. Retrieved 2020-05-11.
28. ^ "APS Member History". search.amphilsoc.org. Retrieved 2021-05-27.
29. ^ "F.A. Wilczek". Royal Netherlands Academy of Arts and Sciences. Archived from the original on 14 February 2016. Retrieved 14 February 2016.
30. American Academy of Achievement
    .
31. ^ "New honorary doctorates in science and technology – Uppsala University, Sweden". www.uu.se. Retrieved 2016-02-03.
32. ^ Anas, Brittany (April 18, 2011). "Nobel Prize Winner Frank Wilczek to lecture at CU Boulder". Daily Camera.
33. ^ "Frank Wilczek". Templeton Prize. 2022. Retrieved May 11, 2022.
34. ^ "Nobel physics laureate Frank Wilczek wins Templeton Prize for work on science, spirituality links". The Washington Times. Retrieved 2022-05-12.
35. ^ "Frank Wilczek". Royal Netherlands Academy of Arts and Sciences. 2002. Archived from the original on November 28, 2020. Retrieved May 11, 2022.
36. doi:10.1103/PhysRevLett.40.279
    .
37. doi:10.1103/PhysRevLett.40.223
    .
38. ^ Overbye, Dennis (17 June 2020). "Seeking dark matter, they detected another mystery". The New York Times.
39. ^ Wilczek, Frank (7 January 2016). "Time's (almost) reversible arrow". Quanta Magazine. Retrieved 17 June 2020.
40. ^ "Homing in on Axions?" (Physics.aps.org, April 9, 2018)
41. ^ Letzter, Rafi (June 17, 2020). "Physicists Announce Potential Dark Matter Breakthrough". Scientific American. Retrieved September 22, 2020. A team of physicists has made what might be the first-ever detection of an axion. Axions are unconfirmed, hypothetical ultralight particles from beyond the Standard Model of particle physics, which describes the behavior of subatomic particles. Theoretical physicists first proposed the existence of axions in the 1970s in order to resolve problems in the math governing the strong force, which binds particles called quarks together. But axions have since become a popular explanation for dark matter, the mysterious substance that makes up 85% of the mass of the universe, yet emits no light.
42. ^ Falk, Dan (June 23, 2020). "Is Dark Matter Made of Axions?". Scientific American. Retrieved September 22, 2020. Then, in 1977 Helen Quinn and the late Roberto Peccei, both then at Stanford University, proposed a solution: perhaps there is a hitherto unknown field that pervades all of space and suppresses the neutron's asymmetries. Later, theoretical physicists Frank Wilczek and Steven Weinberg deduced that if the Standard Model were tweaked to allow such a field, it would imply the existence of a new particle, dubbed the axion. (Wilczek got the idea for the name from a brand of laundry detergent.)
43. ^ "Anyons, anyone?". Symmetry Magazine. August 31, 2011. Retrieved September 24, 2020. In 1982 physicist Frank Wilczek gave these interstitial particles the name anyon ... 'Any anyon can be anything between a boson or a fermion', Keilmann says. 'Wilczek is a funny guy.'
44. ISSN 0953-8585
    . Retrieved September 25, 2020. In the early 1980s I named the hypothetical new particles 'anyons', the idea being that anything goes – but I did not lose much sleep anticipating their discovery. Very soon afterwards, however, Bert Halperin at Harvard University found the concept of anyons useful in understanding certain aspects of the fractional quantum Hall effect, which describes the modifications that take place in electronics at low temperatures in strong magnetic fields.
45. doi:10.1103/PhysRevLett.52.1583
    . The appearance of fractional statistics in the present context is strongly reminiscent of the fractional statistics introduced by Wilczek to describe charged particles tied to "magnetic flux tubes" in two dimensions.
46. ^ ^{a b} Najjar, Dana (May 12, 2020). "'Milestone' Evidence for Anyons, a Third Kingdom of Particles". Wired. Retrieved September 18, 2020. In the early 1980s, physicists first used these conditions to observe the 'fractional quantum Hall effect', in which electrons come together to create so-called quasiparticles that have a fraction of the charge of a single electron. (If it seems strange to call the collective behavior of electrons a particle, think of the proton, which is itself made up of three quarks.) In 1984, a seminal two-page paper by Wilczek, Daniel Arovas and John Robert Schrieffer showed that these quasiparticles had to be anyons.
47. ^ Dumé, Isabelle (May 28, 2020). "Anyons bunch together in a 2D conductor". Physics World. Retrieved September 26, 2020. The existence of anyons – which get their name from the fact that their behaviour is neither fermion-like or boson-like – was predicted in the early 1980s by the theoretical physicist Frank Wilczek. Soon afterwards, another physicist, Bert Halperin, found that anyons could explain certain aspects of the fractional quantum Hall effect, which describes the changes that take place in electronics at low temperatures in strong magnetic fields. Then, in 1984, Dan Arovas, Bob Schrieffer and Wilczek proved that a successful theory of the fractional quantum Hall effect does indeed require particles that are neither bosons or fermions.
48. S2CID 215551196
    .
49. Wired
    .
50. ^ Ball, Phillip (July 17, 2018). "In Search of Time Crystals". Physics World. Retrieved March 23, 2019. "We discovered experimentally that discrete time crystals not only exist, but that this phase is also remarkably robust." Mikhail Lukin, Harvard University
51. ^ Woo, Marcus (September 2018). "'Quantum Atmospheres' May Reveal Secrets of Matter". Quanta Magazine. Retrieved 11 May 2020.
52. doi:10.1103/PhysRevB.99.201104
    .
53. S2CID 213899274
    .
54. doi:10.1063/1.2809542
    .

External links

Wikimedia Commons has media related to Frank Wilczek.

Wikiquote has quotations related to Frank Wilczek.

• Frank Wilczek on Nobelprize.org
• Frank Wilczek on INSPIRE-HEP
• Papers in ArXiv
• "The Quirk of the Quark": article about Frank Wilczek by K. C. Cole in Esquire (December, 1984)
• Wilczek on anyons and superconductivity (April, 1991)
• The World's Numerical Recipe (April 26, 2001)
• Blog of the Wilczek family's Nobel adventures (2004)
• ForaTV: The Large Hadron Collider and Unified Field Theory (September 25, 2008)
• Frank Wilczek explains Einstein's massive contributions to science (2009)
• Freeman Dyson, "Leaping into the Grand Unknown: Review of The Lightness of Being", The New York Review of Books 56(6). (April 9, 2009)
• Frank Wilczek discusses his book "The Lightness of Being" on the 7th Avenue Project Radio Show (November 29, 2009)
• A television interview with Frank Wilczek on
  YouTube
  for Cambridge University Television (February, 2011)
• A radio interview with Frank Wilczeck Archived 2012-04-22 at the
  Lewis Burke Frumkes
  Radio Show (April 10, 2011)
• "A Prodigy Who Cracked Open the Cosmos": article about Frank Wilczek by Claudia Dreifus published in Quanta Magazine (January 12, 2021)