Exploring the Photon-Number Distribution of Bimodal Microlasers with a Transition Edge Sensor
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Christian Schneider | Thomas Lettau | Stephan Reitzenstein | Marco Schmidt | Jan Wiersig | Elisabeth Schlottmann | Martin Kamp | M. Kamp | C. Schneider | S. Reitzenstein | J. Beyer | J. Wiersig | S. Hofling | Sven Hofling | E. Schlottmann | M. Helversen | H. Leymann | T. Lettau | Felix Kruger | Marco Schmidt | Martin von Helversen | Heinrich A. M. Leymann | Felix Kruger | Jorn Beyer | M. Schmidt
[1] S. Reitzenstein,et al. Coherence properties of high-β elliptical semiconductor micropillar lasers , 2007 .
[2] Aaron J. Miller,et al. Counting near-infrared single-photons with 95% efficiency. , 2008, Optics express.
[3] S. Reitzenstein,et al. Photon statistics of semiconductor microcavity lasers. , 2007, Physical review letters.
[4] R. Sillitto. The Quantum Theory of Light , 1974 .
[5] L. Grenouillet,et al. Electrically driven high-Q quantum dot-micropillar cavities , 2008, 2008 Conference on Lasers and Electro-Optics and 2008 Conference on Quantum Electronics and Laser Science.
[6] Karlsson,et al. Definition of a laser threshold. , 1994, Physical review. A, Atomic, molecular, and optical physics.
[7] F. Arecchi,et al. 1A4 - Photocount distributions and field statistics , 1966 .
[8] M. Kamp,et al. Mode-switching induced super-thermal bunching in quantum-dot microlasers , 2016 .
[9] J. Wiersig,et al. Effect of direct dissipative coupling of two competing modes on intensity fluctuations in a quantum-dot-microcavity laser , 2016 .
[10] Zach DeVito,et al. Opt , 2017 .
[11] Johann Peter Reithmaier,et al. Lasing in high-Q quantum-dot micropillar cavities , 2006 .
[12] Carmichael,et al. Photon statistics of a cavity-QED laser: A comment on the laser-phase-transition analogy. , 1994, Physical review. A, Atomic, molecular, and optical physics.
[13] S. Reitzenstein,et al. On thresholdless lasing features in high-$\beta$ nitride nanobeam cavities: a quantum optical study , 2016, 1603.06447.
[14] Christian Schneider,et al. AlAs∕GaAs micropillar cavities with quality factors exceeding 150.000 , 2007 .
[15] Andrew G. Glen,et al. APPL , 2001 .
[16] Lee. External photodetection of cavity radiation. , 1993, Physical review. A, Atomic, molecular, and optical physics.
[17] Antonio-José Almeida,et al. NAT , 2019, Springer Reference Medizin.
[18] M. Kamp,et al. Unconventional collective normal-mode coupling in quantum-dot-based bimodal microlasers , 2015 .
[19] Sae Woo Nam,et al. Detection of single infrared, optical, and ultraviolet photons using superconducting transition edge sensors , 1998 .
[20] A. Jechow,et al. Enhanced two-photon excited fluorescence from imaging agents using true thermal light , 2013, Nature Photonics.
[21] Marlan O. Scully,et al. Quantum Theory of an Optical Maser. 1. General Theory , 1967 .
[22] Technische Universitat Berlin,et al. Intensity fluctuations in bimodal micropillar lasers enhanced by quantum-dot gain competition , 2013, 1301.3417.
[23] J. Wiersig,et al. Expectation value based equation-of-motion approach for open quantum systems: A general formalism , 2014 .
[24] J. Mørk,et al. High beta lasing in micropillar cavities with adiabatic layer design , 2013 .
[25] R. H. Brown,et al. Correlation between Photons in two Coherent Beams of Light , 1956, Nature.
[26] Christian Schneider,et al. Emission from quantum-dot high-β microcavities: transition from spontaneous emission to lasing and the effects of superradiant emitter coupling , 2016, Light: Science & Applications.
[27] De-Zhong Cao,et al. Two-photon subwavelength lithography with thermal light , 2010 .
[28] W. Denk,et al. Two-photon laser scanning fluorescence microscopy. , 1990, Science.
[29] Frank Jahnke,et al. Semiconductor model for quantum-dot-based microcavity lasers , 2007 .
[30] A. Schawlow. Lasers , 2018, Acta Ophthalmologica.
[31] Christian Schneider,et al. Injection locking of quantum dot microlasers operating in the few photon regime , 2016, 1604.02817.
[32] John M. Martinis,et al. Demonstration of a low-noise near-infrared photon counter with multiphoton discrimination , 2003 .
[33] F. Raineri,et al. Asymmetric mode scattering in strongly coupled photonic crystal nanolasers , 2016, 2017 Conference on Lasers and Electro-Optics Europe & European Quantum Electronics Conference (CLEO/Europe-EQEC).
[34] S. Reitzenstein,et al. Photon-Number-Resolving Transition-Edge Sensors for the Metrology of Quantum Light Sources , 2018 .
[35] Xiang Zhang,et al. Plasmon lasers at deep subwavelength scale , 2009, Nature.
[36] M. Bayer,et al. Higher-Order Photon Bunching in a Semiconductor Microcavity , 2009, Science.
[37] Tsuyoshi Murata,et al. {m , 1934, ACML.
[38] D. Drung,et al. Highly Sensitive and Easy-to-Use SQUID Sensors , 2007, IEEE Transactions on Applied Superconductivity.
[39] Y. Ota,et al. Laser oscillation in a strongly coupled single-quantum-dot–nanocavity system , 2009, 0905.3063.
[40] M. Bayer,et al. Direct observation of correlations between individual photon emission events of a microcavity laser , 2009, Nature.
[41] D. Bouwmeester,et al. Self-tuned quantum dot gain in photonic crystal lasers. , 2005, Physical review letters.
[42] Christian Schneider,et al. Giant photon bunching, superradiant pulse emission and excitation trapping in quantum-dot nanolasers , 2016, Nature Communications.
[43] A. Eckardt,et al. Generalized Bose-Einstein condensation into multiple states in driven-dissipative systems. , 2013, Physical review letters.
[44] Antoine Godard,et al. Measuring photon bunching at ultrashort timescale by two-photon absorption in semiconductors , 2009 .
[45] L. Mandel,et al. Coherence theory of the ring laser , 1978 .
[46] A. Gatti,et al. Ghost imaging with thermal light: comparing entanglement and classical correlation. , 2003, Physical review letters.
[47] M. Kamp,et al. Pump-Power-Driven Mode Switching in a Microcavity Device and Its Relation to Bose-Einstein Condensation , 2016, 1612.04312.
[48] Jacob B. Khurgin,et al. How small can “Nano” be in a “Nanolaser”? , 2012 .