1 files changed, 164 insertions, 11 deletions

diff --git a/bibliography.bib b/bibliography.bib
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--- a/bibliography.bib
+++ b/bibliography.bib
@@ -7437,15 +7437,168 @@ doi = {10.1080/09500340.2016.1148212},
 	abstract = "We describe a subluminal laser which is extremely stable against perturbations. It makes use of a composite gain spectrum consisting of a broad background along with a narrow peak. The stability of the laser, defined as the change in frequency as a function of a change in the cavity length, is enhanced by a factor given by the group index, which can be as high as 105 for experimentally realizable parameters. We also show that the fundamental linewidth of such a laser is expected to be smaller by the same factor. We first present an analysis where the gain profile is modeled as a superposition of two Lorentzian functions. We then present a numerical study based on a physical scheme for realizing the composite gain profile. In this scheme, the broad gain is produced by a high pressure buffer-gas loaded cell of rubidium vapor. The narrow gain is produced by using a Raman pump in a second rubidium vapor cell, where optical pumping is used to produce a Raman population inversion. We show close agreement between the idealized model and the explicit model. A subluminal laser of this type may prove to be useful for many applications."
 }
 
-@article{laserFeedbackApplication2017OE,
-author = { Jiyang  Li,Haisha  Niu,Yan Xiong  Niu},
-title = {Laser feedback interferometry and applications: a review},
-journal = {Optical Engineering},
-volume = {56},
-number = {},
-pages = {56 - 56 - 20},
-abstract = {The progress on laser feedback interferometry technology is reviewed. Laser feedback interferometry is a demonstration of interferometry technology applying a laser reflected from an external surface, which has features including simple structure, easy alignment, and high sensitivity. Theoretical analysis including the Lang–Kobayashi model and three-mirror model are conducted to explain the modulation of the laser output properties under the feedback effect. In particular, the effect of frequency and polarization shift feedback effects are analyzed and discussed. Various applications on various types of lasers are introduced. The application fields range from metrology, to physical quantities, to laser parameters and other applications. The typical applications of laser feedback technology in industrial and research fields are discussed. Laser feedback interferometry has great potential to be further exploited and applied.},
-year = {2017},
-doi = {10.1117/1.OE.56.5.050901},
-URL = {https://doi.org/10.1117/1.OE.56.5.050901}
+@article{laserFeedbackApplicationReview2017OE,
+	author = { Jiyang  Li,Haisha  Niu,Yan Xiong  Niu},
+	title = {Laser feedback interferometry and applications: a review},
+	journal = {Optical Engineering},
+	volume = {56},
+	number = {5},
+	pages = {050901},
+	abstract = {The progress on laser feedback interferometry technology is
+	     reviewed. Laser feedback interferometry is a demonstration of
+	     interferometry technology applying a laser reflected from an
+	     external surface, which has features including simple structure,
+	     easy alignment, and high sensitivity. Theoretical analysis
+	     including the Lang–Kobayashi model and three-mirror model are
+	     conducted to explain the modulation of the laser output properties
+	     under the feedback effect. In particular, the effect of frequency
+	     and polarization shift feedback effects are analyzed and
+	     discussed. Various applications on various types of lasers are
+	     introduced. The application fields range from metrology, to
+	     physical quantities, to laser parameters and other applications.
+	     The typical applications of laser feedback technology in
+	     industrial and research fields are discussed. Laser feedback
+	     interferometry has great potential to be further exploited and
+	     applied.},
+	year = {2017},
+	doi = {10.1117/1.OE.56.5.050901},
+	URL = {https://doi.org/10.1117/1.OE.56.5.050901}
 }
+
+@article{distanceMeasurementReview2017,
+	author = {Yoon-Soo Jang and Seung-Woo Kim},
+	title = {Compensation of the refractive index of air in laser interferometer for distance measurement: A review},
+	journal = {Int. J. Precis. Eng. Manuf.},
+	volume = {18},
+	number = {12},
+	pages = {1881 -- 1890},
+	abstract = {We review the progress made for compensation of the refractive
+	     index of air in laser-based distance measurements in the field of
+	     precision engineering. First, a comprehensive analysis is
+	     introduced to clarify how the overall measurement uncertainty is
+	     affected by the refractive index of the ambient air, particularly
+	     for dimensional metrology and geodetic survey using laser in
+	     open-air environment. Second, it is explained that the measurement
+	     uncertainty can be improved to a 10 -8 level by adopting empirical
+	     dispersion formulae describing the relation of the laser wavelength
+	     with the environment parameters such as temperature, pressure,
+	     humidity and carbon dioxide concentration. Third, the principle of
+	     refractometers is given to describe that the measurement
+	     uncertainty can be enhanced to a 10 -9 level by identifying the
+	     refractive index of air real time in well-controlled environmental
+	     conditions. Fourth, the two-color compensation method is discussed
+	     which enables precise laser-based distance measurement simply by
+	     using two different wavelengths without actual identification of
+	     the refractive index of open air. Finally, the recent approach of
+	     using femtosecond lasers is described with emphasis on the
+	     performance of the two-color method can be enhanced to a 10 -9
+	     level by stabilizing the pulse repetition rate as well as frequency
+	     stability of ultrashort pulse lasers with reference to the atomic
+	     clocks.},
+	year = {2017},
+	doi = {10.1007/s12541-017-0217-y}
+}
+
+@article{advanceLIGO2018prd,
+	title = {Sensitivity of the Advanced LIGO detectors at the beginning of gravitational wave astronomy},
+	author = {Martynov, D.V. and {\em et al}},
+	allauthors={Martynov, D. V. and Hall, E. D. and Abbott, B. P. and
+		Abbott, R. and Abbott, T. D. and Adams, C. and Adhikari, R. X.
+		and Anderson, R. A. and Anderson, S. B. and Arai, K. and Arain,
+		M. A. and Aston, S. M. and Austin, L. and Ballmer, S. W. and
+		Barbet, M. and Barker, D. and Barr, B. and Barsotti, L. and
+		Bartlett, J. and Barton, M. A. and Bartos, I. and Batch, J. C.
+		and Bell, A. S. and Belopolski, I. and Bergman, J. and
+		Betzwieser, J. and Billingsley, G. and Birch, J. and Biscans,
+		S. and Biwer, C. and Black, E. and Blair, C. D. and Bogan, C.
+		and Bond, C. and Bork, R. and Bridges, D. O. and Brooks, A. F.
+		and Brown, D. D. and Carbone, L. and Celerier, C. and Ciani, G.
+		and Clara, F. and Cook, D. and Countryman, S. T. and Cowart, M.
+		J. and Coyne, D. C. and Cumming, A. and Cunningham, L. and
+		Damjanic, M. and Dannenberg, R. and Danzmann, K. and Costa, C.
+		F. Da Silva and Daw, E. J. and DeBra, D. and DeRosa, R. T. and
+		DeSalvo, R. and Dooley, K. L. and Doravari, S. and Driggers, J.
+		C. and Dwyer, S. E. and Effler, A. and Etzel, T. and Evans, M.
+		and Evans, T. M. and Factourovich, M. and Fair, H. and
+		Feldbaum, D. and Fisher, R. P. and Foley, S. and Frede, M. and
+		Freise, A. and Fritschel, P. and Frolov, V. V. and Fulda, P.
+		and Fyffe, M. and Galdi, V. and Giaime, J. A. and Giardina, K.
+		D. and Gleason, J. R. and Goetz, R. and Gras, S. and Gray, C.
+		and Greenhalgh, R. J. S. and Grote, H. and Guido, C. J. and
+		Gushwa, K. E. and Gustafson, E. K. and Gustafson, R. and
+		Hammond, G. and Hanks, J. and Hanson, J. and Hardwick, T. and
+		Harry, G. M. and Haughian, K. and Heefner, J. and Heintze, M.
+		C. and Heptonstall, A. W. and Hoak, D. and Hough, J. and
+		Ivanov, A. and Izumi, K. and Jacobson, M. and James, E. and
+		Jones, R. and Kandhasamy, S. and Karki, S. and Kasprzack, M.
+		and Kaufer, S. and Kawabe, K. and Kells, W. and Kijbunchoo, N.
+		and King, E. J. and King, P. J. and Kinzel, D. L. and Kissel,
+		J. S. and Kokeyama, K. and Korth, W. Z. and Kuehn, G. and Kwee,
+		P. and Landry, M. and Lantz, B. and Le Roux, A. and Levine, B.
+		M. and Lewis, J. B. and Lhuillier, V. and Lockerbie, N. A. and
+		Lormand, M. and Lubinski, M. J. and Lundgren, A. P. and
+		MacDonald, T. and MacInnis, M. and Macleod, D. M. and
+		Mageswaran, M. and Mailand, K. and M\'arka, S. and M\'arka, Z.
+		and Markosyan, A. S. and Maros, E. and Martin, I. W. and
+		Martin, R. M. and Marx, J. N. and Mason, K. and Massinger, T.
+		J. and Matichard, F. and Mavalvala, N. and McCarthy, R. and
+		McClelland, D. E. and McCormick, S. and McIntyre, G. and
+		McIver, J. and Merilh, E. L. and Meyer, M. S. and Meyers, P. M.
+		and Miller, J. and Mittleman, R. and Moreno, G. and Mueller, C.
+		L. and Mueller, G. and Mullavey, A. and Munch, J. and Murray,
+		P. G. and Nuttall, L. K. and Oberling, J. and O'Dell, J. and
+		Oppermann, P. and Oram, Richard J. and O'Reilly, B. and
+		Osthelder, C. and Ottaway, D. J. and Overmier, H. and Palamos,
+		J. R. and Paris, H. R. and Parker, W. and Patrick, Z. and Pele,
+		A. and Penn, S. and Phelps, M. and Pickenpack, M. and Pierro,
+		V. and Pinto, I. and Poeld, J. and Principe, M. and Prokhorov,
+		L. and Puncken, O. and Quetschke, V. and Quintero, E. A. and
+		Raab, F. J. and Radkins, H. and Raffai, P. and Ramet, C. R. and
+		Reed, C. M. and Reid, S. and Reitze, D. H. and Robertson, N. A.
+		and Rollins, J. G. and Roma, V. J. and Romie, J. H. and Rowan,
+		S. and Ryan, K. and Sadecki, T. and Sanchez, E. J. and
+		Sandberg, V. and Sannibale, V. and Savage, R. L. and Schofield,
+		R. M. S. and Schultz, B. and Schwinberg, P. and Sellers, D. and
+		Sevigny, A. and Shaddock, D. A. and Shao, Z. and Shapiro, B.
+		and Shawhan, P. and Shoemaker, D. H. and Sigg, D. and
+		Slagmolen, B. J. J. and Smith, J. R. and Smith, M. R. and
+		Smith-Lefebvre, N. D. and Sorazu, B. and Staley, A. and Stein,
+		A. J. and Stochino, A. and Strain, K. A. and Taylor, R. and
+		Thomas, M. and Thomas, P. and Thorne, K. A. and Thrane, E. and
+		Tokmakov, K. V. and Torrie, C. I. and Traylor, G. and Vajente,
+		G. and Valdes, G. and van Veggel, A. A. and Vargas, M. and
+		Vecchio, A. and Veitch, P. J. and Venkateswara, K. and Vo, T.
+		and Vorvick, C. and Waldman, S. J. and Walker, M. and Ward, R.
+		L. and Warner, J. and Weaver, B. and Weiss, R. and Welborn, T.
+		and We\ss{}els, P. and Wilkinson, C. and Willems, P. A. and
+		Williams, L. and Willke, B. and Wilmut, I. and Winkelmann, L.
+		and Wipf, C. C. and Worden, J. and Wu, G. and Yamamoto, H. and
+		Yancey, C. C. and Yu, H. and Zhang, L. and Zucker, M. E. and
+		Zweizig, J.},
+	journal = {Phys. Rev. D},
+	volume = {93},
+	issue = {11},
+	pages = {112004},
+	numpages = {19},
+	year = {2016},
+	month = {Jun},
+	publisher = {American Physical Society},
+	doi = {10.1103/PhysRevD.93.112004},
+	url = {https://link.aps.org/doi/10.1103/PhysRevD.93.112004}
+}
+
+@article{opticalAtomicClocksReview2015,
+	title = {Optical atomic clocks},
+	author = {Ludlow, Andrew D. and Boyd, Martin M. and Ye, Jun and Peik, E. and Schmidt, P. O.},
+	journal = {Rev. Mod. Phys.},
+	volume = {87},
+	issue = {2},
+	pages = {637--701},
+	numpages = {65},
+	year = {2015},
+	month = {Jun},
+	publisher = {American Physical Society},
+	doi = {10.1103/RevModPhys.87.637},
+	url = {https://link.aps.org/doi/10.1103/RevModPhys.87.637}
+}
+