John Joannopoulos

John Joannopoulos
Joannopoulos in 2010
Born(1947-04-26)April 26, 1947
New York City, U.S.
DiedAugust 17, 2025(2025-08-17) (aged 78)
Alma materUniversity of California, Berkeley
Scientific career
FieldsPhysics
InstitutionsMIT
ThesisElectronic structure of complex crystalline and amorphous semiconductors (1974)
Doctoral advisorMarvin L. Cohen
Doctoral students

John D. Joannopoulos (April 26, 1947 – August 17, 2025) was an American physicist, focused in condensed matter theory. He was the Francis Wright Davis Professor of Physics at Massachusetts Institute of Technology, an Elected Member of the National Academy of Sciences (NAS), an Elected Member of the American Academy of Arts and Sciences (AAA&S), and an Elected Fellow of the American Association for the Advancement of Science (AAAS) and American Physical Society (APS).

Life and career

Joannopoulos was born on April 26, 1947, in New York City to Greek parents.[50] He is the recipient of numerous awards and honors. Most recently, in 2015, the Optical Society of America (OSA) awarded him the Max Born Award and the APS awarded him the Aneesur Rahman Prize for Computational Physics, both significant awards.[51][52][53][54][55]

Joannopoulos was also the director of the Institute for Soldier Nanotechnologies. He first gained that position in 2006.[56]

Joannopoulos had been on the MIT faculty since 1974. He held his BA and PhD from the University of California, Berkeley, the latter received in 1974. His doctoral studies, advised by Marvin L. Cohen, focused on electronic structure of complex crystalline and amorphous semiconductors.[50]

Joannopoulos had helped set the theoretical foundations of key computational techniques for realistic and microscopic studies of complex materials systems, including the electronic, vibrational, and optical structure of crystalline and amorphous solids, their surfaces, interfaces, and defects; localization in disordered systems; and the first ab-initio studies of phase transitions and critical phenomena. In the early nineties, he also helped spawn the development of a new class of materials (photonic crystals) that provide new mechanisms to control the flow of light and have revolutionized the fields of optical and lightwave physics.[57]

His former students include Nobel Laureate Robert B. Laughlin, along with professors Yaneer Bar-Yam, Shanhui Fan, Steven G. Johnson, Eugene J. Mele, Michelle Povinelli, Karin M. Rabe, David Vanderbilt,[58] and many other faculty at major universities.[57]

Joannopoulos died on August 17, 2025, at the age of 78.[57]

See also

References

  1. ^ Mele, Eugene. "New theoretical methods for the study of the electronic structure of solids". MIT Libraries. Retrieved August 20, 2025.
  2. ^ Laughlin, Robert. "The structure and excitations of amorphous solids and surfaces". MIT Libraries. Retrieved August 20, 2025.
  3. ^ Pollard, William. "Electrons and phonons in pyramidally bonded solids". MIT Libraries. Retrieved August 20, 2025.
  4. ^ Vanderbilt, David. "A theoretical study of defects in amorphous semiconductors". MIT Libraries. Retrieved August 20, 2025.
  5. ^ Douglas, Alfred Douglas. "Localization and low temperature transport in disordered one-dimensional systems". MIT Libraries. Retrieved August 20, 2025.
  6. ^ Lee, Dung-Hai. "Elementary excitations at surfaces". MIT Libraries. Retrieved August 20, 2025.
  7. ^ Allan, Douglas. "New theoretical studies of structure and defects in hydrogenated amorphous silicon". MIT Libraries. Retrieved August 20, 2025.
  8. ^ Bar-Yam, Yaneer. "Microscopic theory of the dynamics of defects in semiconductors". MIT Libraries. Retrieved August 20, 2025.
  9. ^ Kaxiras, Efthimios. "Ab Initio theory of polar surfaces of binary compound semiconductors". MIT Libraries. Retrieved August 20, 2025.
  10. ^ Rabe, Karin. "Ab initio statistical mechanics of structural phase transitions". MIT Libraries. Retrieved August 20, 2025.
  11. ^ Needels, Mark. "Quantum molecular dynamics simulation of surface and defect structure in solids". MIT Libraries. Retrieved August 20, 2025.
  12. ^ Wang, Jing. "Ab-initio theoretical studies of surfaces of semiconductors". MIT Libraries. Retrieved August 20, 2025.
  13. ^ Rappe, Andrew. "Ab initio theoretical studies of transition-metal, molecular, and photonic band-gap materials". MIT Libraries. Retrieved August 20, 2025.
  14. ^ Arias, Tomás. "New analytic and computational techniques for finite temperature condensed matter systems". MIT Libraries. Retrieved August 20, 2025.
  15. ^ Brommer, Karl. "Ab initio study of the Si(111)-(7x7) surface reconstruction : a challenge for massively parallel computation". MIT Libraries. Retrieved August 20, 2025.
  16. ^ Cho, Kyeongjae. "New methods for the calculation of dynamical properties of many-particle systems". MIT Libraries. Retrieved August 20, 2025.
  17. ^ Capaz, Rodrigo. "Ab initio studies of semiconductors : defects, surfaces and interfaces". MIT Libraries. Retrieved August 20, 2025.
  18. ^ Chen, Jerry. "A Electromagnetic field computation and photonic band gap devices". MIT Libraries. Retrieved August 20, 2025.
  19. ^ Fan, Shanhui. "Photonic crystals : theory and device applications". MIT Libraries. Retrieved August 20, 2025.
  20. ^ Park, Ickjin. "Dynamics of an excess electron in water". MIT Libraries. Retrieved August 20, 2025.
  21. ^ Abrams, Daniel. "Quantum algorithms". MIT Libraries. Retrieved August 20, 2025.
  22. ^ Ismail-Beigi, Sohrab. "New perspectives on ab initio calculation and physical insights gained through linkage to continuum theories". MIT Libraries. Retrieved August 20, 2025.
  23. ^ Devenyi, Adrian. "New iterative minimization techniques in complex crystalline systems". MIT Libraries. Retrieved August 20, 2025.
  24. ^ Fink, Yoel. "Polymeric photonic crystals". MIT Libraries. Retrieved August 20, 2025.
  25. ^ Mekis, Attila. "Theoretical design of photonic crystal devices for integrated optical circuits". MIT Libraries. Retrieved August 20, 2025.
  26. ^ Wang, Tairan. "Ab-initio design of materials performance". MIT Libraries. Retrieved August 20, 2025.
  27. ^ Skorobogatiy, Maksim. "Computational studies of dynamics and propagation in condensed matter physics". MIT Libraries. Retrieved August 20, 2025.
  28. ^ Johnson, Steven. "Photonic crystals: From theory to practice". MIT Libraries. Retrieved August 20, 2025.
  29. ^ Appelbaum, Ian. "Ballistic electrons : microscopy, spectroscopy, devices and luminescence". MIT Libraries. Retrieved August 20, 2025.
  30. ^ Reed, Evan. "Optical, electronic, and dynamical phenomena in the shock compression of condensed matter". MIT Libraries. Retrieved August 20, 2025.
  31. ^ Weitz, Joshua. "Generalized contact processes in ecology". MIT Libraries. Retrieved August 20, 2025.
  32. ^ Yeşilleten, Dicle. "Ab initio study of magnetic effects at material interfaces". MIT Libraries. Retrieved August 20, 2025.
  33. ^ Engeness, Torkel. "Multiscale ab initio approaches to materials physics". MIT Libraries. Retrieved August 20, 2025.
  34. ^ Huang, Kerwyn Casey. "The rise and fall of structure in physics: Polaritonic photonic crystals, melting, and min-protein oscillations". MIT Libraries. Retrieved August 20, 2025.
  35. ^ Yi, Ya Sha. "On-chip silicon based photonic structures : photonic band gap and quasi-photonic band gap materials". MIT Libraries. Retrieved August 20, 2025.
  36. ^ Luo, Chiyan. "Anomalous photon phenomena in electromagnetic crystal systems". MIT Libraries. Retrieved August 20, 2025.
  37. ^ Povinelli, Michelle. "Characteristics of defect modes, slow light, and disorder in photonic crystals". MIT Libraries. Retrieved August 20, 2025.
  38. ^ Ibanescu, Mihai. "Cylindrical photonic crystals". MIT Libraries. Retrieved August 20, 2025.
  39. ^ Evans, Matthew. "Nanoscale structure and transport: From atoms to devices". MIT Libraries. Retrieved August 20, 2025.
  40. ^ Chan, David. "Defects, thermal phenomena and design in photonic crystal systems". MIT Libraries. Retrieved August 20, 2025.
  41. ^ Zhou, Fei. "Models for transition metal oxides and for protein design". MIT Libraries. Retrieved August 20, 2025.
  42. ^ Bermel, Peter. "Active materials in photonic crystals". MIT Libraries. Retrieved August 20, 2025.
  43. ^ Karalis, Aristeidis. "Novel photonic phenomena in nanostructured material systems with applications and mid-range efficient insensitive wireless energy-transfer". MIT Libraries. Retrieved August 20, 2025.
  44. ^ Chan, Maria. "Atomistic and ab initio prediction and optimization of thermoelectric and photovoltaic properties". MIT Libraries. Retrieved August 20, 2025.
  45. ^ Ghebrebrhan, Michael. "Anomalous phenomena and spectral tailoring in photonic crystals". MIT Libraries. Retrieved August 20, 2025.
  46. ^ Rodriguez-Wong, Alejandro. "Fluctuation-induced interactions and nonlinear nanophotonics". MIT Libraries. Retrieved August 20, 2025.
  47. ^ McCauley, Alexander. "Novel applications of Maxwell's equations to quantum and thermal phenomena". MIT Libraries. Retrieved August 20, 2025.
  48. ^ Kim, Sejoong. "Inelastic transport In molecular junctions from first principles". MIT Libraries. Retrieved August 20, 2025.
  49. ^ Liu, David. "Nonlinear design in nanophotonics". MIT Libraries. Retrieved August 20, 2025.
  50. ^ a b Array of Contemporary American Physicists listing
  51. ^ "John Joannopoulos". aaas.org. Archived from the original on May 24, 2018. Retrieved May 14, 2017.
  52. ^ "John Joannopoulos". mit.edu. Retrieved May 14, 2017.
  53. ^ "John Joannopoulous". mit.edu. Archived from the original on May 31, 2018. Retrieved May 14, 2017.
  54. ^ "Lab". mit.edu. Retrieved May 14, 2017.
  55. ^ American Physical Society article on Joannopoulos getting prize
  56. ^ "Institute for Soldier Nanotechnologies bio of Joannopoulos". Archived from the original on May 31, 2018. Retrieved May 15, 2017.
  57. ^ a b c Chu, Jennifer (August 19, 2025). "Professor John Joannopoulos, photonics pioneer and Institute for Soldier Nanotechnologies director, dies at 78". MIT News. Massachusetts Institute of Technology. Retrieved August 19, 2025.
  58. ^ "Members of the Ab-Initio Physics Research Group". Retrieved May 2, 2024.
allikas: https://en.wikipedia.org/wiki/John_Joannopoulos