From 78a011546cde8c859b46ed06103f749577cb07f0 Mon Sep 17 00:00:00 2001 From: "Eugeniy E. Mikhailov" Date: Sun, 8 Jul 2018 21:38:56 -0400 Subject: biblio updated with Irina's refs --- bibliography.bib | 235 +++++++++++++++++++++++++++++++++++++++++++++++++++++-- 1 file changed, 228 insertions(+), 7 deletions(-) diff --git a/bibliography.bib b/bibliography.bib index 8dd3f6f..22112e0 100644 --- a/bibliography.bib +++ b/bibliography.bib @@ -234,11 +234,13 @@ Several dispersionlike features in the magnetic field dependence of the nonlinea and Yudin, V. I.", title={Experimental investigation of the dark pseudoresonance on the ${D}1$ line of the $^{87}${R}b atom excited by a linearly polarized field}, journal = {Journal of Experimental and Theoretical Physics Letters}, + issn = {0021-3640}, + keyword = {Physics and Astronomy}, year="2005", month="Oct", day="01", volume="82", - number="8", + issue="8", pages="477--481", abstract={The measurements of the metrological characteristics (amplitude, width, and shift in the magnetic field) of the dark pseudoresonance, which was proposed by Kazakov et al. [quant-ph/0506167] as the reference resonance for an atomic frequency standard, are reported. It has been shown that the characteristics of the pseudoresonance are worse than those of the unsplit electromagnetically induced transparency resonance for the excitation scheme with the lin{\textbardbl}lin polarization on the D1 line of the 87Rb atom.}, issn="1090-6487", @@ -938,9 +940,10 @@ We develop an analytical theory of dark resonances that accounts for the full at author = "E. Arimondo", title = "Coherent population trapping in laser spectroscopy", pages = "259-354", + chapter = "5", booktitle = "Progress in Optics", editor = "E. Wolf", - publisher = "Elsevier", + publisher = "Elsevier, Amsterdam", year = "1996", volume = "35", } @@ -5528,7 +5531,8 @@ canceled abstract = { Preliminary results from an experimental study of slow light in anti-relaxation-coated Rb vapour cells are presented, and the construction and testing of such cells are described. The slow ground state decoherence rate allowed by coated cell walls leads to a dual-structured electromagnetically induced transparency (EIT) spectrum with a very narrow (< 100 Hz) transparency peak on top of a broad pedestal. Such dual-structured EIT permits optical probe pulses to propagate with greatly reduced group velocity on two time scales. Ongoing efforts to optimize the pulse delay in such coated cell systems are discussed. } } -@article{novikova2011pra_eit_coated_cells, +@alias{novikova2011pra_eit_coated_cells=klein2011pra_eit_coated_cells} +@article{klein2011pra_eit_coated_cells, title = {Electromagnetically induced transparency in paraffin-coated vapor cells}, author = {Klein, M. and Hohensee, M. and Phillips, D. F. and Walsworth, R. L.}, journal = {Phys. Rev. A}, @@ -6760,6 +6764,9 @@ volume = {23}, number = {05}, pages = {661-680}, year = {2009}, +doi = {10.1142/S0217984909019028}, + +URL = {http://www.worldscientific.com/doi/abs/10.1142/S0217984909019028}, doi = {10.1142/S0217984909019028} } @@ -6974,8 +6981,6 @@ abstract = {The combination of MEMS fabrication with atomic clocks has enabled a URL = {http://dx.doi.org/10.1063/1.4919841} } - - @article{romalisJAP09, author = {S. J. Seltzer and M. V. Romalis}, title = {High-temperature alkali vapor cells with antirelaxation surface coatings}, @@ -6988,8 +6993,6 @@ abstract = {The combination of MEMS fabrication with atomic clocks has enabled a URL = {http://dx.doi.org/10.1063/1.3236649} } - - @incollection{Shah201021, title = "Chapter 2 - Advances in Coherent Population Trapping for Atomic Clocks ", editor = "E. Arimondo, P.R. Berman and C.C. Lin", @@ -7140,3 +7143,221 @@ url="http://dx.doi.org/10.1134/1.2142864" doi = {10.1103/PhysRevA.96.013835} } +@article{yashchukRSI00, + author = "Yashchuk, Valeriy V. and Budker, Dmitry and Davis, John R.", + title = "Laser frequency stabilization using linear magneto-optics", + journal = "Review of Scientific Instruments", + year = "2000", + volume = "71", + number = "2", + eid = , + pages = "341-346", + url = "http://scitation.aip.org/content/aip/journal/rsi/71/2/10.1063/1.1150205", + doi = "http://dx.doi.org/10.1063/1.1150205" +} + +@article{Guidry:17, +author = {Melissa A. Guidry and Elena Kuchina and Irina Novikova and Eugeniy E. Mikhailov}, +journal = {J. Opt. Soc. Am. B}, +keywords = {Line shapes and shifts; Coherent optical effects; Diode lasers; High power lasers; Laser beams; Laser sources; Optical fields; Tunable diode lasers}, +number = {10}, +pages = {2244--2249}, +publisher = {OSA}, +title = {Characterization of frequency stability in electromagnetically induced transparency-based atomic clocks using a differential detection scheme}, +volume = {34}, +month = {Oct}, +year = {2017}, +url = {http://josab.osa.org/abstract.cfm?URI=josab-34-10-2244}, +doi = {10.1364/JOSAB.34.002244}, +abstract = {We investigate a recently proposed scheme for differential detection of the magneto-optical rotation effect and its application to electromagnetically induced transparency (EIT) atomic clocks \[Opt. Lett.40, 3703 (2015)OPLEDP0146-959210.1364/OL.40.003703\]. This scheme utilizes a linearly polarized bichromatic laser field that is EIT-resonant with alkali atoms. The results of our study reveal that the suppression of the laser noise can substantially improve the signal-to-noise ratio in EIT atomic clocks. Our preliminary results demonstrate an order of magnitude improvement in clock stability under some conditions when incorporating the differential detection scheme.}, +} + +@article{Belfi:09, +author = {J. Belfi and G. Bevilacqua and V. Biancalana and S. Cartaleva and Y. Dancheva and K. Khanbekyan and L. Moi}, +journal = {J. Opt. Soc. Am. B}, +keywords = {Coherent optical effects; All-optical devices; Frequency modulated lasers; Laser beam propagation; Laser beams; Laser sources; Magnetic fields; Stray light}, +number = {5}, +pages = {910--916}, +publisher = {OSA}, +title = {Dual channel self-oscillating optical magnetometer}, +volume = {26}, +month = {May}, +year = {2009}, +url = {http://josab.osa.org/abstract.cfm?URI=josab-26-5-910}, +doi = {10.1364/JOSAB.26.000910}, +abstract = {We report on a two-channel magnetometer based on nonlinear magneto-optical rotation in a Cs glass cell with buffer gas. The Cs atoms are optically pumped and probed by free running diode lasers tuned to the D2 line. A wide frequency modulation of the pump laser is used to produce both synchronous Zeeman optical pumping and hyperfine repumping. The magnetometer works in an unshielded environment, and a spurious signal from distant magnetic sources is rejected by means of differential measurement. In this regime the magnetometer simultaneously gives the magnetic field modulus and the field difference. Rejection of the common-mode noise allows for high-resolution magnetometry with a sensitivity of 2 pT/sqrt Hz. This sensitivity, in conjunction with long-term stability and a large bandwidth, makes it possible to detect water proton magnetization and its free induction decay in a measurement volume of 5 cm3.}, +} + +@article{GuEPL2017, + author={Huifang Lin and Yuan Tian and Bozhong Tan and Sihong Gu}, + title={Differential detection scheme for compact CPT atomic clocks}, + journal={EPL (Europhysics Letters)}, + volume={119}, + number={2}, + pages={23001}, + url={http://stacks.iop.org/0295-5075/119/i=2/a=23001}, + year={2017}, + abstract={A scheme is investigated for a coherent population trapping (CPT) atomic clock, wherein the polarization of a beam produced by a vertical-cavity surface-emitting laser is converted to an elliptically polarized beam that interacts with alkali atoms, where the CPT signal is extracted by differentially detecting the magneto-optically rotated light within the transmitted beam. The scheme eliminates the spin-polarized trap state of the atoms and the unwanted background signal, and suppresses in the CPT signal the noise converted from the laser noise. This result reveals the promise of this scheme for realizing a compact CPT atomic clock possessing a significantly improved frequency stability compared to current compact CPT atomic clock devices, coupled with similar power consumption, volume, and cost therewith.} +} + +@ARTICLE{kitchinIEEE2008, +author={V. Gerginov and S. Knappe and V. Shah and L. Hollberg and J. Kitching}, +journal={IEEE Transactions on Instrumentation and Measurement}, +title={Laser Noise Cancellation in Single-Cell CPT Clocks}, +year={2008}, +volume={57}, +number={7}, +pages={1357-1361}, +keywords={atomic clocks;laser noise;light polarisation;measurement standards;radiation pressure;amplitude noise;atomic clocks;buffer gas mixture;circularly polarized beams;coherent population trapping;common-mode noise;differential detection;laser frequency;laser noise cancellation;noise suppression;single rubidium vapor cell;single-cell CPT clocks;Atomic clocks;coherent population trapping (CPT);compact frequency references;diode lasers;noise reduction;vertical-cavity surface-emitting lasers (VCSELs)}, +doi={10.1109/TIM.2007.915123}, +ISSN={0018-9456}, +month={July},} + +@article{CamparoPhysRevA.59.728, + title = {Conversion of laser phase noise to amplitude noise in a resonant atomic vapor: The role of laser linewidth}, + author = {Camparo, J. C. and Coffer, J. G.}, + journal = {Phys. Rev. A}, + volume = {59}, + issue = {1}, + pages = {728--735}, + numpages = {0}, + year = {1999}, + month = {Jan}, + publisher = {American Physical Society}, + doi = {10.1103/PhysRevA.59.728}, + url = {https://link.aps.org/doi/10.1103/PhysRevA.59.728} +} + +@article{Radojicic:15, +author = {Ivan S. Radoji\v{c}i\'{c} and Milan Radonji\'{c} and Marina M. Leki\'{c} and Zoran D. Gruji\'{c} and Dragan Luki\'{c} and Branislav Jelenkovi\'{c}}, +journal = {J. Opt. Soc. Am. B}, +keywords = {Coherent optical effects; Linewidth; Electric fields; Laser beam propagation; Laser beams; Magnetic fields; Optical Bloch equations; Spontaneous emission}, +number = {3}, +pages = {426--430}, +publisher = {OSA}, +title = {Raman\&\#x2013;Ramsey electromagnetically induced transparency in the configuration of counterpropagating pump and probe in vacuum Rb cell}, +volume = {32}, +month = {Mar}, +year = {2015}, +url = {http://josab.osa.org/abstract.cfm?URI=josab-32-3-426}, +doi = {10.1364/JOSAB.32.000426}, +abstract = {Counterpropagating, spatially separated hollow pump and coaxial probe laser beams generate narrow Zeeman electromagnetically induced transparency (EIT) resonances in the vacuum Rb cell. The lasers are locked to D2 line transition Fg$=$2\&\#x2192;Fe$=$1 of Rb87. For the probe laser beam intensity between 0.1 and 3.0\&\#x2009;\&\#x2009;mW/cm2 this Ramsey-type configuration yields dual-structured resonances having a narrow peak on top of a broader pedestal. Linewidths of the narrow peak are nearly independent of the probe laser beam intensity and of the probe diameter (for diameters 0.8 and 2.7\&\#xA0;mm), provided that the dark region between the pump and the probe beams is fixed. At the probe laser beam intensities below 0.1\&\#x2009;\&\#x2009;mW/cm2 Zeeman EIT is a single narrow resonance. With this geometry of laser beams, and at low probe intensity, the presence of the pump enables the probe EIT, i.e., the probe transmission becomes enhanced in a narrow spectral window. Accompanying theoretical model showed good quantitative agreement with the measurements.}, +} + +@article{LezamaPhysRevA.81.023801, + title = {Raman-Ramsey multizone spectroscopy in a pure rubidium vapor cell}, + author = {Failache, H. and Lenci, L. and Lezama, A.}, + journal = {Phys. Rev. A}, + volume = {81}, + issue = {2}, + pages = {023801}, + numpages = {5}, + year = {2010}, + month = {Feb}, + publisher = {American Physical Society}, + doi = {10.1103/PhysRevA.81.023801}, + url = {https://link.aps.org/doi/10.1103/PhysRevA.81.023801} +} + +@article{RamseyPhysRev.78.695, + title = {A Molecular Beam Resonance Method with Separated Oscillating Fields}, + author = {Ramsey, Norman F.}, + journal = {Phys. Rev.}, + volume = {78}, + issue = {6}, + pages = {695--699}, + numpages = {0}, + year = {1950}, + month = {Jun}, + publisher = {American Physical Society}, + doi = {10.1103/PhysRev.78.695}, + url = {https://link.aps.org/doi/10.1103/PhysRev.78.695} +} + +@article{EnglandJPB2012, + author={D G England and P S Michelberger and T F M Champion and K F Reim and K C Lee and M R Sprague and X-M Jin and N K Langford and W S +Kolthammer and J Nunn and I A Walmsley}, + title={High-fidelity polarization storage in a gigahertz bandwidth quantum memory}, + journal={Journal of Physics B: Atomic, Molecular and Optical Physics}, + volume={45}, + number={12}, + pages={124008}, + url={http://stacks.iop.org/0953-4075/45/i=12/a=124008}, + year={2012}, + abstract={We demonstrate a dual-rail optical Raman memory inside a polarization interferometer; this enables us to store polarization-encoded information at GHz bandwidths in a room-temperature atomic ensemble. By performing full process tomography on the system, we measure up to 97 ± 1% process fidelity for the storage and retrieval process. At longer storage times, the process fidelity remains high, despite a loss of efficiency. The fidelity is 86 ± 4% for 1.5 μs storage time, which is 5000 times the pulse duration. Hence, high fidelity is combined with a large time-bandwidth product. This high performance, with an experimentally simple setup, demonstrates the suitability of the Raman memory for integration into large-scale quantum networks.} +} + +@article{FigueroaPhysRevApplied.8.034023, + title = {Ultralow-Noise Room-Temperature Quantum Memory for Polarization Qubits}, + author = {Namazi, Mehdi and Kupchak, Connor and Jordaan, Bertus and Shahrokhshahi, Reihaneh and Figueroa, Eden}, + journal = {Phys. Rev. Applied}, + volume = {8}, + issue = {3}, + pages = {034023}, + numpages = {6}, + year = {2017}, + month = {Sep}, + publisher = {American Physical Society}, + doi = {10.1103/PhysRevApplied.8.034023}, + url = {https://link.aps.org/doi/10.1103/PhysRevApplied.8.034023} +} + +@article{Higginbottom:15, +author = {D. B. Higginbottom and J. Geng and G. T. Campbell and M. Hosseini and M. T. Cao and B. M. Sparkes and J. Bernu and N. P. Robins and P. K. Lam and B. C. Buchler}, +journal = {Opt. Express}, +keywords = {Atomic and molecular physics; Coherent optical effects; Optical data storage; Optical memories; Circular polarization; Faraday effect; Free induction decay; Magnetic fields; Optical depth; Optical fields}, +number = {19}, +pages = {24937--24944}, +publisher = {OSA}, +title = {Dual-rail optical gradient echo memory}, +volume = {23}, +month = {Sep}, +year = {2015}, +url = {http://www.opticsexpress.org/abstract.cfm?URI=oe-23-19-24937}, +doi = {10.1364/OE.23.024937}, +abstract = {We introduce a scheme for the parallel storage of frequency separated signals in an optical memory and demonstrate that this dual-rail storage is a suitable memory for high fidelity frequency qubits. The two signals are stored simultaneously in the Zeeman-split Raman absorption lines of a cold atom ensemble using gradient echo memory techniques. Analysis of the split-Zeeman storage shows that the memory can be configured to preserve the relative amplitude and phase of the frequency separated signals. In an experimental demonstration dual-frequency pulses are recalled with 35\&\#x00025; efficiency, 82\&\#x00025; interference fringe visibility, and 6\&\#x000B0; phase stability. The fidelity of the frequency-qubit memory is limited by frequency-dependent polarisation rotation and ambient magnetic field fluctuations, our analysis describes how these can be addressed in an alternative configuration.}, +} + +@article{SargsyanJMO2015, +author = {Armen Sargsyan and Claude Leroy and Yevgenya Pashayan-Leroy and Stefka Cartaleva and David Sarkisyan}, +title = {High-contrast dark resonances on the D1 line in cesium nanocell: the advantages compared with the other alkali D lines}, +journal = {Journal of Modern Optics}, +volume = {62}, +number = {10}, +pages = {769-777}, +year = {2015}, +publisher = {Taylor & Francis}, +doi = {10.1080/09500340.2015.1006699}, + +URL = { + https://doi.org/10.1080/09500340.2015.1006699 + +}, +eprint = { + https://doi.org/10.1080/09500340.2015.1006699 + +} + +} + +@Article{Sargsyan2011, +author="Sargsyan, A. +and Leroy, C. +and Pashayan-Leroy, Y. +and Mirzoyan, R. +and Papoyan, A. +and Sarkisyan, D.", +title="High contrast D 1 line electromagnetically induced transparency in nanometric-thin rubidium vapor cell", +journal="Applied Physics B", +year="2011", +month="Dec", +day="01", +volume="105", +number="4", +pages="767--774", +abstract="The electromagnetically induced transparency (EIT) on the atomic D 1 line of rubidium is studied using a nanometric-thin cell with atomic vapor column length in the range of L=400--800 nm. It is shown that the reduction of the cell thickness by four orders as compared with an ordinary cm-size cell still allows to form an EIT resonance for L=$\lambda$=794 nm with the contrast of up to 40{\%}. Further reduction of thickness to L=$\lambda$/2 leads to significant reduction of EIT contrast, verifying that the key parameter for EIT in wavelength-scale-thickness cells is not the value of L itself but L/$\lambda$ ratio. Remarkable distinctions of EIT formation in nanometric-thin and ordinary cells are demonstrated. Well-resolved splitting of the EIT resonance in a magnetic field for L=$\lambda$ can be used for magnetometry with nanometric spatial resolution. The presented theoretical model well describes the observed results.", +issn="1432-0649", +doi="10.1007/s00340-011-4614-0", +url="https://doi.org/10.1007/s00340-011-4614-0" +} + -- cgit v1.2.3