Title :
Polariton squeezing in semiconductor microcavities
Author :
Baas, A. ; Karr, J.-Ph. ; Houdre, R. ; Giacobino, E.
Author_Institution :
Laboratoire Kastler Brossel, Univ. Pierre et Marie Curie, Paris, France
Abstract :
Measurements on the light going out of the cavity, i.e. the photon part of the polariton field are reported. Squeezing of the polariton field is then deduced. From the calculations made, the best squeezing rate is expected in the vicinity of a bistability turning point. The sample used in these experiments is a high finesse GaAs microcavity containing one InGaAs quantum well with low indium content, with a small angle between the two mirrors. The light source is a single-mode tunable cw Ti:sapphire laser with a linewidth of the order of 1 MHz. The laser beam is power-stabilized using an electro-optic modulator and spatially filtered by a 2 m-long single mode fiber. Noise measurement is achieved by homodyne detection. From the squeezing measured outside the cavity, a 9% squeezing of the polariton field is inferred. This result opens the way to the generation of nonclassical states of light and matter in semiconductor microcavities.
Keywords :
electro-optical modulation; gallium arsenide; homodyne detection; indium compounds; laser stability; microcavities; noise measurement; optical bistability; optical squeezing; polaritons; semiconductor quantum wells; spatial filters; 2 m; GaAs microcavity; InGaAs; InGaAs quantum well; bistability turning point; electro-optic modulator; homodyne detection; laser beam power stabilization; noise measurement; polariton squeezing; semiconductor microcavities; single-mode tunable cw Ti:sapphire laser; spatial filtering; Fiber lasers; Gallium arsenide; Indium gallium arsenide; Laser modes; Laser noise; Lasers and electrooptics; Microcavities; Mirrors; Quantum well lasers; Turning;
Conference_Titel :
Quantum Electronics Conference, 2003. EQEC '03. European
Print_ISBN :
0-7803-7733-8
DOI :
10.1109/EQEC.2003.1314205
