Yasunobu Nakamura (中村 泰信 Nakamura Yasunobu) is a Japanese physicist. He is a professor at the University of Tokyo's Research Center for Advanced Science and Technology (RCAST)[6] and the Principal Investigator of the Superconducting Quantum Electronics Research Group (SQERG) at the Center for Emergent Matter Science (CEMS) within RIKEN.[7] He has contributed primarily to the area of quantum information science,[8] particularly in superconducting quantum computing and hybrid quantum systems.[9][10][11]

Yasunobu Nakamura
Yasunobu Nakamura
Born1968
Known forWork with "hybrid quantum information systems".[1][2] First demonstration of coherent control of a Cooper pair box-based superconducting charge qubit.[3][4]
AwardsMicius Quantum Prize 2021
Scientific career
FieldsQuantum information science, Superconducting quantum computing

Education and early work

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While a child, Nakamura's family moved from Osaka to Hinode, Tokyo, where he would gain his early education.[12] He obtained his Bachelor of Science (1990), Master of Science (1992), and Ph.D. (2011) degrees at the University of Tokyo. In 1999, as a researcher at NEC, Nakamura and collaborators Yuri Pashkin and Jaw-Shen Tsai demonstrated "electrical coherent control of a qubit in a solid-state electronic device"[3] and in 2001 "realized the first measurement of the Rabi oscillations associated with the transition between two Josephson levels in the Cooper pair box"[13][14] in a configuration developed by Michel Devoret and colleagues in 1998.[13][15]

In 2000, Nakamura was featured as a "Younger Scientist" by the Japan Society of Applied Physics for his work at NEC in "quantum-state control of nanoscale superconducting devices."[16] From 2001-2002, he visited the group of Hans Mooij [de] at TU Delft on a sabbatical from NEC, where he worked with Irinel Chiorescu, Kees Harmans, and Mooij to create the first flux qubit.[17][18][19] In 2003, he was named one of MIT Technology Review's top innovators under 35 years old, in which editors noted that "Nakamura and a collaborator got two qubits to interact in a manner that had been predicted but never demonstrated" at the time.[20]

Current work

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As of 3 October 2016, the Japan Science and Technology Agency (科学技術振興機構) announced funding for Nakamura's work through their Exploratory Research for Advanced Technology (ERATO) program.[21] The project, entitled Macroscopic Quantum Machines,[22] seeks to dramatically improve quantum state control technology to further the field of quantum computing. Of principal focus is the development of a highly scalable platform for implementing quantum information processing techniques, as well as the creation of hybrid quantum systems which interface with microwave quantum optics. In an article in Nikkei Science [ja] in 2018, it was announced that work towards the construction of a quantum computer with 100 superconducting qubits was underway.[23] In 2019, the Japanese Ministry of Education, Culture, Sports, Science and Technology launched a quantum technology project known as QLEAP, with Nakamura as the team leader for the quantum information processing component.[24] The project aims to develop superconducting quantum computers and other quantum technologies over a ten-year period, by increasing collaboration between academia and industry.

 
A flux qubit and superconducting microwave cavity form a coupled system that connects to a parametric phase-locked oscillator. In the paper "Single microwave-photon detector using an artificial Λ-type three-level system" published in Nature Communications in 2016, Nakamura and collaborators manipulated this three-level system in such a way that single photons were detected with an "efficiency of 0.66±0.06 with a low dark-count probability of 0.014±0.001 and a reset time of ~400 ns."[25]

In past years, Nakamura and collaborators have published their findings on the efficient detection of single microwave frequency photons,[25] the suppression of quasiparticles in superconducting quantum computing environments for the improvement of qubit coherence times,[26] the development of "a deterministic scheme to generate maximal entanglement between remote superconducting atoms, using a propagating microwave photon as a flying qubit",[27] and the realization of a hybrid quantum system by the strong, coherent coupling between a collective magnetic mode of a ferromagnetic sphere and a superconducting qubit.[1]

More recently, results have been published in which superconducting qubits were used to resolve quanta of magnon number states,[28][29] to create a quantitatively non-classical photon number distribution,[30] to measure fluctuations in a surface acoustic wave (SAW) resonator,[31] and to measure an itinerant microwave photon in a quantum nondemolition (QND) detection experiment.[32][33] A superconducting circuit was later used to realize information-to-work conversion by a Maxwell's demon,[34] radio waves and optical light were optomechanically coupled to surface acoustic waves,[35] and an ordered vortex lattice in a Josephson junction array was observed.[36]

Nakamura has spoken several times at quantum information science conferences and seminars, including at the University of Vienna,[37] the Institute for Theoretical Atomic Molecular and Optical Physics at Harvard University,[38][39] the National Center of Competence in Research's Quantum Science and Technology Monte Verità conference,[40] the Institute for Quantum Computing at the University of Waterloo,[41] the Institute for Molecular Engineering at the University of Chicago[42] the Institute for Quantum Optics and Quantum Information (IQOQI),[43] and the Yale Quantum Institute at Yale University.[44]

In 2020, Nakamura was named as a fellow of the American Physical Society for "the first demonstration of coherent time-dependent manipulation of superconducting qubits, and for contributions to the development of superconducting quantum circuits, microwave quantum optics, and hybrid quantum systems".[45]

Honors and awards

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References

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  1. ^ a b Y. Tabuchi, S. Ishino, A. Noguchi, T. Ishikawa, R. Yamazaki, K. Usami, and Y. Nakamura, "Coherent coupling between a ferromagnetic magnon and a superconducting qubit", Science 349, 405-408 (2015), doi:10.1126/science.aaa3693
  2. ^ Y. Tabuchi, S. Ishino, T. Ishikawa, R. Yamazaki, K. Usami, and Y. Nakamura, "Hybridizing Ferromagnetic Magnons and Microwave Photons in the Quantum Limit", Physical Review Letters 113, 083603 (2014), doi:10.1103/PhysRevLett.113.083603, arxiv:1405.1913
  3. ^ a b Y. Nakamura, Yu. A. Pashkin and J.- S. Tsai, "Coherent control of macroscopic quantum states in a single-Cooper-pair box", Nature 398, 786-788 (1999), doi:10.1038/19718, arXiv:9904003
  4. ^ T. Yamamoto, Yu. A. Pashkin, O. Astafiev, Y. Nakamura, and J.- S. Tsai, "Demonstration of conditional gate operation using superconducting charge qubits", Nature 425, 941-944 (2003), doi:10.1038/nature02015, arxiv:0311067
  5. ^ "RIKEN Tuning Into Quantum Computers". 2007-08-17. Retrieved 2017-06-19.
  6. ^ "Research Groups". Retrieved 2016-12-21.
  7. ^ "Superconducting Quantum Electronics Research Group". Retrieved 2020-10-22.
  8. ^ T. D. Ladd, F. Jelezko, R. Laflamme, Y. Nakamura, C. Monroe, and J.L. O'Brien, "Quantum computers", Nature 464, 45-53 (2010), doi:10.1038/nature08812, arxiv:1009:2267
  9. ^ "マイナビニュース". 2015-07-10. Retrieved 2016-12-22.
  10. ^ "ようこそ量子 Interview". 2016-11-15. Retrieved 2016-12-22.
  11. ^ "Science Daily 2015". 2015-08-03. Retrieved 2016-12-22.
  12. ^ "UTokyo Voices 066". 2019-06-20. Retrieved 2019-06-21.
  13. ^ a b "Bell Prize 2013". Archived from the original on 2014-06-04. Retrieved 2016-12-21.
  14. ^ Y. Nakamura, Y.A. Pashkin, and J.S. Tsai, "Rabi Oscillations in a Josephson-Junction Charge Two-Level System", Physical Review Letters 87, 246601 (2001), doi:10.1103/PhysRevLett.87.246601
  15. ^ V. Bouchiat, D. Vion, P. Joyez, D. Esteve and M. H. Devoret, "Quantum coherence with a single Cooper pair", Physica Scripta T76, 165-170 (1998), doi:10.1238/Physica.Topical.076a00165
  16. ^ "JSAP Younger Scientists" (PDF). Retrieved 2016-12-21.
  17. ^ I. Chiorescu, Y. Nakamura, C. J. P. M. Harmans, and J. E. Mooij, "Coherent Quantum Dynamics of a Superconducting Flux Qubit", Science 299, 5614, 1869-1871, (2003), doi:10.1126/science.1081045, arxiv:0305461
  18. ^ J. Clarke, "Flux Qubit Completes the Hat Trick", Science 299, 5614, 1850-1851, (2003), doi:10.1126/science.1083001
  19. ^ "The first Delft qubit". 2017-11-04. Retrieved 2017-11-04.
  20. ^ a b "Innovators Under 35". Retrieved 2016-12-21.
  21. ^ "戦略的創造研究推進事業における". Retrieved 2016-12-21.
  22. ^ "研究総括および研究領域". Retrieved 2016-12-21.
  23. ^ "超電導量子ビットを創始 100ビットを目指す". September 2018. Retrieved 2019-06-21.
  24. ^ "光・量子飛躍フラッグシッププログラム(Q-LEAP)". Retrieved 2019-04-03.
  25. ^ a b K. Inomata, Z. Lin, K. Koshino, W. D. Oliver, J.- S. Tsai, T. Yamamoto, and Y. Nakamura, "Single microwave-photon detector using an artificial Λ-type three-level system", Nature Communications 7, 12303 (2016), doi:10.1038/ncomms12303
  26. ^ S. Gustavsson, F. Yan, G. Catelani, J. Bylander, A. Kamal, J. Birenbaum, D. Hover, D. Rosenberg, G. Samach, A. P. Sears, S. J. Weber, J. L. Yoder, J. Clarke, A. J. Kerman, F. Yoshihara, Y. Nakamura, T. P. Orlando, and W. D. Oliver, "Suppressing relaxation in superconducting qubits by quasiparticle pumping", Science 354, 6319, 1573-1577 (2016), doi:10.1126/science.aah5844
  27. ^ K. Koshino, K. Inomata, Z. R. Lin, Y. Tokunaga, T. Yamamoto, and Y. Nakamura, "Theory of Deterministic Entanglement Generation between Remote Superconducting Atoms", Physical Review Applied 7, 064006 (2017), doi:10.1103/PhysRevApplied.7.064006
  28. ^ D. Lachance-Quiriom, Y. Tabuchi, S. Ishino, A. Noguchi, T. Ishikawa, R. Yamazaki, and Y. Nakamura, "Resolving quanta of collective spin excitations in a millimeter-sized ferromagnet", Science Advances 3, 7, e1603150 (2017), doi:10.1126/sciadv.1603150
  29. ^ "Quantifying quanta". 2017-11-22. Retrieved 2019-04-03.
  30. ^ S. Kono, Y. Masuyama, T. Ishikawa, Y. Tabuchi, R. Yamazaki, K. Usami, K. Koshino, and Y. Nakamura, "Nonclassical Photon Number Distribution in a Superconducting Cavity under a Squeezed Drive", Physical Review Letters 119, 023602 (2017), doi:10.1103/PhysRevLett.119.023602
  31. ^ A. Noguchi, R. Yamazaki, Y. Tabuchi, and Y. Nakamura, "Qubit-Assisted Transduction for a Detection of Surface Acoustic Waves near the Quantum Limit", Physical Review Letters 119, 180505 (2017), doi:10.1103/PhysRevLett.119.180505
  32. ^ S. Kono, K. Koshino, Y. Tabuchi, A. Noguchi, and Y. Nakamura, "Quantum non-demolition detection of an itinerant microwave photon", Nature Physics 14, 546-549 (2018), doi:10.1038/s41567-018-0066-3
  33. ^ "Viewpoint: Single Microwave Photons Spotted on the Rebound". 2018-04-23. Retrieved 2019-04-03.
  34. ^ Y. Masuyama, K. Funo, Y. Murashita, A. Noguchi, S. Kono, Y. Tabuchi, R. Yamazaki, M. Ueda, and Y. Nakamura, "Information-to-work conversion by Maxwell’s demon in a superconducting circuit quantum electrodynamical system", Nature Communications 9, 1291 (2018), doi:10.1038/s41467-018-03686-y
  35. ^ A. Okada, F. Oguro, A. Noguchi, Y. Tabuchi, R. Yamazaki, K. Usami, and Y. Nakamura, "Cavity Enhancement of Anti-Stokes Scattering via Optomechanical Coupling with Surface Acoustic Waves", Physical Review Applied 10, 024002 (2018), doi:10.1103/PhysRevApplied.10.024002
  36. ^ R. Cosmic, K. Ikegami, Z. Lin, K. Inomata, J. M. Taylor, and Y. Nakamura, "Circuit-QED-based measurement of vortex lattice order in a Josephson junction array", Physical Review B 98, 060501(R) (2018), doi:10.1103/PhysRevB.98.060501
  37. ^ "University of Vienna 2014". Retrieved 2016-12-21.
  38. ^ "ITAMP". Retrieved 2016-12-21.
  39. ^ "ITAMP Video". YouTube. 2015-07-15. Retrieved 2016-12-22.
  40. ^ "NCCR QSIT". Retrieved 2016-12-21.
  41. ^ "IQC 2016". Retrieved 2016-12-21.
  42. ^ "IME Distinguished Colloquium Series". Retrieved 2019-04-03.
  43. ^ "IQOQI Colloquium". Retrieved 2019-04-03.
  44. ^ "YQI Colloquium". Retrieved 2019-04-03.
  45. ^ a b "APS Fellows". Retrieved 2020-12-01.
  46. ^ "JSAP Younger Scientists" (PDF). Retrieved 2017-01-24.
  47. ^ "Prize Winners". Millennium Science Forum. Retrieved 2019-04-03.
  48. ^ "2016 Sir Martin Wood Prize for Japan". Oxford Instruments. Retrieved 2017-01-24.
  49. ^ "NEC Awards FY1999". Retrieved 2017-01-24.
  50. ^ "Agilent Technologies Prize". 2004-06-17. Retrieved 2016-12-21.
  51. ^ "Simon Memorial Prize: Past Winners". Retrieved 2017-06-13.
  52. ^ "RCAST News". 2014. Retrieved 2017-01-24.
  53. ^ "JSAP Outstanding Achievement Award Recipients". Retrieved 2019-06-21.
  54. ^ "第19回 応用物理学会業績賞". Retrieved 2019-06-21.
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