Multidimensional quantum well laser and temperature dependence of its threshold current Y Arakawa, H Sakaki Applied physics letters 40 (11), 939-941, 1982 | 4533 | 1982 |
Observation of the coupled exciton-photon mode splitting in a semiconductor quantum microcavity C Weisbuch, M Nishioka, A Ishikawa, Y Arakawa Physical review letters 69 (23), 3314, 1992 | 3092 | 1992 |
Controlling the Spontaneous Emission Rate of Single Quantum Dots<? format?> in a Two-Dimensional Photonic Crystal D Englund, D Fattal, E Waks, G Solomon, B Zhang, T Nakaoka, ... Physical review letters 95 (1), 013904, 2005 | 1224 | 2005 |
Semiconductor quantum dots: Technological progress and future challenges FP García de Arquer, DV Talapin, VI Klimov, Y Arakawa, M Bayer, ... Science 373 (6555), eaaz8541, 2021 | 1043 | 2021 |
Quantum well lasers--Gain, spectra, dynamics Y Arakawa, A Yariv IEEE journal of quantum electronics 22 (9), 1887-1899, 1986 | 655 | 1986 |
A gallium nitride single-photon source operating at 200 K S Kako, C Santori, K Hoshino, S Götzinger, Y Yamamoto, Y Arakawa Nature materials 5 (11), 887-892, 2006 | 549 | 2006 |
III-V/Si hybrid photonic devices by direct fusion bonding K Tanabe, K Watanabe, Y Arakawa Scientific reports 2 (1), 349, 2012 | 494 | 2012 |
Efficient carrier relaxation mechanism in InGaAs/GaAs self-assembled quantum dots based on the existence of continuum states Y Toda, O Moriwaki, M Nishioka, Y Arakawa Physical Review Letters 82 (20), 4114, 1999 | 492 | 1999 |
Room-temperature triggered single photon emission from a III-nitride site-controlled nanowire quantum dot MJ Holmes, K Choi, S Kako, M Arita, Y Arakawa Nano letters 14 (2), 982-986, 2014 | 454 | 2014 |
Rapid carrier relaxation in self-assembled As/GaAs quantum dots B Ohnesorge, M Albrecht, J Oshinowo, A Forchel, Y Arakawa Physical Review B 54 (16), 11532, 1996 | 435 | 1996 |
Laser oscillation in a strongly coupled single-quantum-dot–nanocavity system M Nomura, N Kumagai, S Iwamoto, Y Ota, Y Arakawa Nature Physics 6 (4), 279-283, 2010 | 421 | 2010 |
Over 1.5 μm light emission from InAs quantum dots embedded in InGaAs strain-reducing layer grown by metalorganic chemical vapor deposition J Tatebayashi, M Nishioka, Y Arakawa Applied Physics Letters 78 (22), 3469-3471, 2001 | 354 | 2001 |
Photonic crystal nanocavity based on a topological corner state Y Ota, F Liu, R Katsumi, K Watanabe, K Wakabayashi, Y Arakawa, ... Optica 6 (6), 786-789, 2019 | 349 | 2019 |
Quantum noise and dynamics in quantum well and quantum wire lasers Y Arakawa, K Vahala, A Yariv Applied physics letters 45 (9), 950-952, 1984 | 345 | 1984 |
Theory of gain, modulation response, and spectral linewidth in AlGaAs quantum well lasers Y Arakawa, A Yariv IEEE Journal of quantum electronics 21 (10), 1666-1674, 1985 | 342 | 1985 |
Highly uniform InGaAs/GaAs quantum dots (∼ 15 nm) by metalorganic chemical vapor deposition J Oshinowo, M Nishioka, S Ishida, Y Arakawa Applied physics letters 65 (11), 1421-1423, 1994 | 339 | 1994 |
Room temperature lasing at blue wavelengths in gallium nitride microcavities T Someya, R Werner, A Forchel, M Catalano, R Cingolani, Y Arakawa Science 285 (5435), 1905-1906, 1999 | 333 | 1999 |
Silicon photonics for next generation system integration platform Y Arakawa, T Nakamura, Y Urino, T Fujita IEEE Communications Magazine 51 (3), 72-77, 2013 | 327 | 2013 |
Pentacene-based organic field-effect transistors M Kitamura, Y Arakawa Journal of Physics: Condensed Matter 20 (18), 184011, 2008 | 318 | 2008 |
Progress in quantum-dot single photon sources for quantum information technologies: A broad spectrum overview Y Arakawa, MJ Holmes Applied Physics Reviews 7 (2), 2020 | 303 | 2020 |