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-rw-r--r-- | bibliography.bib | 95 |
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diff --git a/bibliography.bib b/bibliography.bib index bea2cd3..01bd7b2 100644 --- a/bibliography.bib +++ b/bibliography.bib @@ -998,16 +998,19 @@ anomalous dispersion region. abstract = {}, } -@Article{kuzmich2001prl, - author = "A. Kuzmich and A. Dogariu and L. J. Wang and P. W. Milonni and R. Y. Chiao", - title = "Signal velocity, causality, and quantum noise in superluminal light pulse propagation", - journal = "Phys. Rev. Lett.", - year = "2001", - month = "APR", - volume = "86", - number = "18", - pages = "3925-3929", - abstract = {}, +@alias{kuzmich2001prl=ChiaoPhysRevLett.86.3925} +@article{ChiaoPhysRevLett.86.3925, + title = {Signal Velocity, Causality, and Quantum Noise in Superluminal Light Pulse Propagation}, + author = {Kuzmich, A. and Dogariu, A. and Wang, L. J. and Milonni, P. W. and Chiao, R. Y.}, + journal = {Phys. Rev. Lett.}, + volume = {86}, + issue = {18}, + pages = {3925--3929}, + year = {2001}, + month = {Apr}, + doi = {10.1103/PhysRevLett.86.3925}, + url = {http://link.aps.org/doi/10.1103/PhysRevLett.86.3925}, + publisher = {American Physical Society} } @Article{sautenkov99las, @@ -2852,6 +2855,7 @@ Electromagnetically induced transparency in an optically thick, cold medium crea year = {2007} } +@alias{lvovskyPRL08=lvovsky08prl_sq_eit} @article{lvovsky08prl_sq_eit, author = {J\"{u}rgen Appel and Eden Figueroa and Dmitry Korystov and M. Lobino and A. I. Lvovsky}, @@ -2865,9 +2869,17 @@ Electromagnetically induced transparency in an optically thick, cold medium crea number = {9}, eid = {093602}, numpages = {4}, + issn = {0031-9007}, pages = {093602}, url = {http://link.aps.org/abstract/PRL/v100/e093602}, - doi = {10.1103/PhysRevLett.100.093602} + doi = {10.1103/PhysRevLett.100.093602}, + abstract = {We produce a 600-ns pulse of 1.86-dB squeezed vacuum at 795 nm in + an optical parametric amplifier and store it in a rubidium vapor + cell for 1 mu s using electromagnetically induced transparency. The + recovered pulse, analyzed using time-domain homodyne tomography, + exhibits up to 0.21 +/- 0.04 dB of squeezing. We identify the factors + leading to the degradation of squeezing and investigate the phase + evolution of the atomic coherence during the storage interval.}, } @@ -2947,6 +2959,7 @@ Electromagnetically induced transparency in an optically thick, cold medium crea pages = {833-836} } +@alias{eisaman_2005=eisaman_electromagnetically_2005} @article{eisaman_electromagnetically_2005, title = {Electromagnetically induced transparency with tunable single-photon pulses}, volume = {438}, @@ -4655,6 +4668,7 @@ abstract = {We show experimentally that the presence of a buffer gas in a rubidi } +@alias{HorromJPB12=mikhailov2012sq_pulses} @article{mikhailov2012sq_pulses, author={Travis Horrom and Irina Novikova and Eugeniy E Mikhailov}, title={All-atomic source of squeezed vacuum with full pulse-shape control}, @@ -4942,6 +4956,8 @@ eprint = {http://www.tandfonline.com/doi/pdf/10.1080/09500340903159495} abstract = {A probe light in a squeezed vacuum state was injected into cold $^{87}$Rb atoms with an intense control light in a coherent state. A sub-MHz window was created due to electromagnetically induced transparency, and the incident squeezed vacuum could pass through the cold atoms without optical loss, as was successfully monitored using a time-domain homodyne method.}, } + +@article{HorromPhysRevA.86.023803=mikhailov2012sq_magnetometer} @alias{horromPRA12=mikhailov2012sq_magnetometer} @Article{mikhailov2012sq_magnetometer, title = {Quantum-enhanced magnetometer with low-frequency squeezing}, @@ -5384,3 +5400,60 @@ canceled Antirelaxation coatings in atomic vapor cells allow ground-state coherent spin states to survive many collisions with the cell walls. This reduction in the ground-state decoherence rate gives rise to ultranarrow-bandwidth features in electromagnetically induced transparency (EIT) spectra, which can form the basis of, for example, long-time scale slow and stored light, sensitive magnetometers, and precise frequency standards. Here we study, both experimentally and theoretically, how Zeeman EIT contrast and width in paraffin-coated rubidium vapor cells are determined by cell and laser-beam geometry, laser intensity, and atomic density. Using a picture of Ramsey pulse sequences, where atoms alternately spend “bright” and “dark” time intervals inside and outside the laser beam, we explain the behavior of EIT features in coated cells, highlighting their unique characteristics and potential applications. } } + +@article{AharonovPhysRevLett.81.2190, + title = {Quantum Limitations on Superluminal Propagation}, + author = {Aharonov, Yakir and Reznik, Benni and Stern, Ady}, + journal = {Phys. Rev. Lett.}, + volume = {81}, + issue = {11}, + pages = {2190--2193}, + year = {1998}, + month = {Sep}, + doi = {10.1103/PhysRevLett.81.2190}, + url = {http://link.aps.org/doi/10.1103/PhysRevLett.81.2190}, + publisher = {American Physical Society} +} + +@article{BoydFastlightJO10, + author={Robert W Boyd and Zhimin Shi and Peter W Milonni}, + title={Noise properties of propagation through slow-� and fast-light media}, + journal={Journal of Optics}, + volume={12}, + number={10}, + pages={104007}, + url={http://stacks.iop.org/2040-8986/12/i=10/a=104007}, + year={2010}, + abstract={We consider the fundamental noise properties of propagation through slow-� and fast-light optical media based on gain or loss processes. For purely quantum mechanical reasons, any gain or loss process will add noise to a transmitted light field. We derive a relation between the noise figure describing the decreased signal-to-noise ratio of the transmitted laser pulse and the fractional delay or advancement of the pulse. We apply these results explicitly to the situation of operation on the line center of a gain or loss line. We find that for an ideal gain medium the noise figure never exceeds a factor of two. For a loss medium, there is no limit as to how large the noise figure can become. The increased noise in this case is the result of the random loss of photons from the optical field.} +} + +@article{BoydGauthierScience09, + author = {Boyd, Robert W. and Gauthier, Daniel J.}, + title = {Controlling the Velocity of Light Pulses}, + volume = {326}, + number = {5956}, + pages = {1074-1077}, + year = {2009}, + doi = {10.1126/science.1170885}, + abstract ={It is now possible to exercise a high degree of control over the velocity at which light pulses pass through material media. This velocity, known as the group velocity, can be made to be very different from the speed of light in a vacuum c. Specifically, the group velocity of light can be made much smaller than c, greater than c, or even negative. We present a survey of methods for establishing extreme values of the group velocity, concentrating especially on methods that work in room-temperature solids. We also describe some applications of slow light.}, + URL = {http://www.sciencemag.org/content/326/5956/1074.abstract}, + eprint = {http://www.sciencemag.org/content/326/5956/1074.full.pdf}, + journal = {Science} +} + +@article{NovikovaJOSAB05, + author = {Irina Novikova and Andrey B. Matsko and George R. Welch}, + journal = {J. Opt. Soc. Am. B}, + keywords = {Coherent optical effects; Effects of collisions; Line shapes and shifts; Zeeman effect; Coherent optical effects}, + number = {1}, + pages = {44--56}, + publisher = {OSA}, + title = {Influence of a buffer gas on nonlinear magneto-optical polarization rotation}, + volume = {22}, + month = {Jan}, + year = {2005}, + url = {http://josab.osa.org/abstract.cfm?URI=josab-22-1-44}, + doi = {10.1364/JOSAB.22.000044}, + abstract = {We show experimentally that the presence of a buffer gas in a rubidium vapor cell modifies significantly the nonlinear magneto-optical rotation of polarization of near-resonant light propagating through the cell. We observe not only the well-known narrowing of the nonlinear magneto-optical resonances, but also changes in their shape and visibility. We explain these effects in terms of coherence-preserving, velocity-changing collisions between rubidium and buffer gas atoms.}, +} + |