Publication List

Journals

1.      Photoionization loss in a simultaneous magneto-optical trap of Rb and Sr, Takatoshi Aoki, Yuki Yamanaka, Makoto Takeuchi, Yasuhiro Sakemi, Yoshio Torii, Physical Review A 87, 063426 (2013) (arXiv:1302.6414).

2.      A simplified 461-nm laser system using blue laser diodes and a hollow cathode lamp for laser cooling of Sr, Yosuke Shimada, Yuko Chida, Nozomi Ohtsubo, Takatoshi Aoki, Makoto Takeuchi, Takahiro Kuga, and Yoshio Torii, Review of Scientific Instrument 84, 063101 (2013) (arXiv:1303.1325).

3.      Laser-phase and frequency stabilization using atomic coherence, Yoshio Torii, Hideyasu Tashiro, Nozomi Ohtsubo, and Takatoshi Aoki, Physical Review A 86, 033805 (2012) (arXiv:1201.1985).

4.      Buffer-gas-assisted polarization spectroscopy of 6Li, Nozomi Ohtsubo, Takatoshi Aoki, and Yoshio Torii, Optics Letters 37, 2865 (2012).

5.      A 461 nm Laser System and Hollow-Cathode Lamp Spectroscopy for Magneto-Optical Trapping of Sr Atoms, Takatoshi Aoki, Kotaro Umezawa, Yuki Yamanaka, Naotomo Takemura, Yasuhiro Sakemi, and Yoshio Torii, Journal of the Physical Society of Japan 81, 034401 (2012) .

6.      Precise intensity correlation measurement for atomic resonance fluorescence from optical molasses, Kazuyuki Nakayama, Yutaka Yoshikawa, Hisatoshi Matsumoto, Yoshio Torii, and Takahiro Kuga,  Optics Express 18, 6604 (2010).

7.      Long storage time of collective coherence in an optically trapped Bose-Einstein condensate, Yutaka Yoshikawa, Kazuyuki Nakayama, Yoshio Torii, and Takahiro Kuga, Physical Review A 79, 025601 (2009).

8.      Strong radiation force induced in two-dimensional photonic crystal slab cavities, Hideaki Taniyama, Masaya Notomi, Eiichi Kuramochi, Takayuki Yamamoto, Yutaka Yoshikawa, Yoshio Torii, and Takahiro Kuga, Physical Review. B 78, 165129 (2008).

9.      Design of a high-Q air-slot cavity based on a width-modulated line-defect in a photonic crystal slab, T. Yamamoto, M. Notomi, H. Taniyama, E. Kuramochi, Y. Yoshikawa, Y. Torii, and T. Kuga, Optics Express 16, 13809 (2008).

10.  Holographic Storage of Multiple Coherence Gratings in a Bose-Einstein Condensate, Yutaka Yoshikawa, Kazuyuki Nakayama, Yoshio Torii, and Takahiro Kuga, Physical  Review Letters 99, 220407 (2007).

11.  Large atom number Bose-Einstein condensate machines  Erik W. Streed, Ananth P. Chikkatur, Todd L. Gustavson, Micah Boyd, Yoshio Torii, Dominik Schneble, Gretchen K. Campbell, David E. Pritchard, and Wolfgang Ketterle, Review of  Scientific Instrument 77, 023106 (2006).

12.  Superradiant Light Scattering from Thermal Atomic Vapors, Yutaka Yoshikawa, Yoshio Torii, and Takahiro Kuga, Physical  Review Letters  94, 083602 (2005).

13.  Observation of superradiant Raman scattering in a Bose-Einstein condensate, Yutaka Yoshikawa, Toshiaki Sugiura, Yoshio Torii, and Takahiro Kuga, Phyical Review A 69, 041603 (2004).

14.  Frequency stabilization of a laser diode with use of light-induced birefringence in an atomic vapor, Yutaka Yoshikawa, Takeshi Umeki, Takuro Mukae, Yoshio Torii, and Takahiro Kuga, Applied Optics 42, 6645 (2003).

15.  The Onset of Matter-Wave Amplification in a Superradiant Bose-Einstein Condensate, Dominik Schneble, Yoshio Torii, Micah Boyd, Erik W. Streed, David E. Pritchard, and Wolfgang Ketterle, Science 300, 475 (2003).

16.  Mach-Zehnder Bragg interferometer for a Bose-Einstein Condensate, Y. Torii, Y. Suzuki, T. Sugiura, M. Kozuma, T. Kuga, L. Deng, and E. W. Haglay, Physical Review A 61, 041602 (2000).

17.  Phase-Coherent Amplification of Matter Waves, M. Kozuma, Y. Suzuki, Y. Torii, T. Sugiura, T. Kuga, E. W. Haglay, and L. Deng, Science 286, 2309 (1999).

18.  Pulsed polarization gradient cooling in an optical dipole trap with a Laguerre-Gaussian laser beam, Y. Torii, T. Kuga, N. Shiokawa, T. Hirano, Y. Shimizu, and H. Sasada, The European Physics Journal D 1, 239-242 (1998).

19.  Novel optical trap of atoms with a doughnut beam, T. Kuga, Y. Torii, N. Shiokawa, T. Hirano, Y. Shimizu, and H. Sasada, Physical Review Letters 78, 4713-4716 (1997).

20.  Spectroscopic Properties of Cold Rubidium Atoms in a Magneto-Optic Trap, Y. Torii, N. Shiokawa, Y. Matsuo, T. Hirano, and T. Kuga, Progress in Crystal Growth and Characteristics 33, 413-417 (1996).

 

Reviews (in Japanese)

1.      鳥井寿夫「ボース・アインシュタイン凝縮」(数理科学2014年2月号

2.      鳥井寿夫「レーザー冷却とボース・アインシュタイン凝縮」(「基礎からの量子光学」39章)(オプトロニクス社、2009

3.      鳥井寿夫「レーザー冷却とボース・アインシュタイン凝縮」月刊オプトロニクス2008 1月号228-239

4.      久我隆弘・鳥井寿夫「ボース-アインシュタイン凝縮」現代物理学の歴史II(朝倉物理学大系21 大系編集委員会編)484-496(朝倉書店、2004

5.      鳥井寿夫「ルビジウム原子のボース・アインシュタイン凝縮発生のための実験手法」レーザー研究 第283号 147-153 (2000).

6.      鳥井寿夫「ルビジウム原子気体のボース・アインシュタイン凝縮」物性研究 第724524-529 (1999).

 

シンポジウム・招待口演など

1.      鳥井寿夫「原子集団のディッケ状態とその応用」(研究会「Fundamental Physics using Atoms@東京」200984日東京工業大学大岡山キャンパス 100年記念館3F フェライト会議室)

2.      Y. Torii, The magic of Dicke superradiance in a Bose-Einstein condensate: from matter-wave amplification to single-photon storage, Asian CORE Symposium on Advanced Laser Spectroscopy (September 26, 2007, Kobe University)

3.      Y. Torii, Superradiant light scattering from condensed and non-condensed atoms, The 10th US-Japan Joint Seminar “Fundamental Issues and Applications of Ultracold Atoms and Molecules” (August 23-25, 2006, Breckenridge, Colorado, USA)

4.      鳥井寿夫「コヒーレント原子波の不思議」(分子科学研究会「分子科学のフロンティア領域へ」200662日、自然科学研究機構岡崎コンファレンスセンター)

5.      鳥井寿夫「コヒーレント原子波光学」(日本物理学会 61回年次大会 領域1シンポジウム「超精密計測が拓く原子・分子・光(AMO)科学の最前線」、2006327日、松山大学)

6.      鳥井寿夫「コヒーレント原子波の開く世界」(第1回 原子・分子・光科学(AMO)討論会、200478日、東京大学)

7.      Y. Torii, Light scattering and atom amplification in a Bose-Einstein condensate, Workshop on chemistry of cold molecules (March 25-26, 2004, Kyoto)

 

International Conference

1.      High-performance Apparatus for Making Bose-Einstein Condensates of Rubidium, Micah Boyd, Erik Streed, Gretchen Campbell, Pavel Gorelik, Dominik Schneble, Yoshio Torii, David Pritchard, and Wolfgang Ketterle, ICAP2002 (Cambridge, MA, July 28- August 2, 2002), I35.

2.      Superradiance in a Bose-Einstein condensate in the short-pulse regime, Dominik Schneble, Yoshio Torii, Erik Streed, Micah Boyd, Pavel Gorelik, Gretchen Campbell, David Pritchard, Wolfgang Ketterle, DAMOP2002 (Williamsburg, Virginia, May 28-June 1, 2002), M2.005.

3.      High-performance Apparatus for Bose-Einstein Condensation of Rubidium atoms, Yoshio Torii, Erik Streed, Micah Boyd, Gretchen Campbell, Pavel Gorelik, Dominik Schneble, David Pritchard, and Wolfgang Ketterle, DAMOP2002 (Williamsburg, Virginia, May 28-June 1, 2002), D6.025.

4.      Improved double Magneto-Optic Trap, K. Ito, R. Namiki, K. Kondo, Y. Sasaki, Y. Torii, and T. Hirano, Euroconference on Atom Optics and Interferometry (Corsica, France, July 26-29, 2000).

5.      Realization of Bose-Eintein condensation in a rubidium vapor using a simple double magneto-optical trap, Y. Torii, Y. Suzuki, M. Kozuma, T. Kuga, The Pacific Rim Conference on Laser and Electro-Optics (Seoul, Korea, August 30-September 3, 1999), ThC4.

6.      Atom wave interferometer for a Bose-Einstein condensate with Bragg diffraction", Y. Torii, Y. Suzuki, T. Sugiura, M. Kozuma, T. Kuga, L. Deng, and E. W. Haglay, Quantum Electronics and Laser Science Conference (Baltimore, MD, May 18-23, 1999), PD1.

7.      Optical dipole trap of atoms with a Laguerre-Gaussian beam", Y. Torii, N. Shiokawa T. Hirano T. Kuga, Y. Shimizu, and H. Sasada, The Pacific Rim Conference on Laser and Electro-Optics (Chiba, Japan, July 17, 1997), PD1.11.

8.      Light Amplification without Population Inversion by Using Laser-Cooled Rubidium Atoms", N. Shiokawa, Y. Torii, T. Hirano, and T. Kuga, Quantum Electronics and Laser Science Conference (Baltimore, MD, May 18-23, 1997), PD2.