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Books on the topic 'Linear optical properties'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 February 2022

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1

Papadopoulos, Manthos G., Andrzej J. Sadlej, and Jerzy Leszczynski, eds. Non-Linear Optical Properties of Matter. Dordrecht: Springer Netherlands, 2006. http://dx.doi.org/10.1007/1-4020-4850-5.

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2

Womersley, Martin Nigel. Linear & non-linear optical properties of electro-optic crystals. [s.l.]: typescript, 1996.

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3

Wagnière, Georges Henry. Linear and nonlinear optical properties of molecules. Basel: Helvetica Chimica Acta, 1993.

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4

Wagnière, Georges Henry. Linear and nonlinear optical properties of molecules. Basel: Helvetica Chimica Acta, 1993.

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5

1947-, Ashwell Geoffrey J., Bloor D. 1937-, and Royal Society of Chemistry (Great Britain). Applied Solid State Chemistry Group., eds. Organic Materials for Non-Linear Optics III. Cambridge: Royal Society of Chemistry, 1993.

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6

Whitmore, Alexander Peter. Preparation of heterocyclic systems with potential non-linear optical properties. Norwich: University of East Anglia, 1994.

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7

Ognjanovic, Rade. Some physical and optical properties of linear low density polyethylene. Birmingham: University of Birmingham, 1986.

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8

Jakubiak, Rachel. Linear and nonlinear optics of organic materials VIII: 12-14 August 2008, San Diego, California, USA. Edited by Society of Photo-optical Instrumentation Engineers. Bellingham, Wash: SPIE, 2008.

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9

Symposium E on Synthetic Metals for Non-linear Optics and Electronics (1992 Strasbourg, France). Synthetic metals for non-linear optics and electronics: Proceedings of Symposium E on Synthetic Metals for Non-linear Optics and Electronics of the 1992 E-MRS spring conference, Strasbourg, France, June 2-4 1992. Amsterdam: North-Holland, 1993.

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10

name, No. Complex mediums IV: Beyond linear isotropic dielectrics :4-5 August 2003, San Diego, California, USA. Bellingham, WA: SPIE, 2003.

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11

Jakubiak, Rachel. Linear and nonlinear optics of organic materials VIII: 12-14 August 2008, San Diego, California, USA. Edited by Society of Photo-optical Instrumentation Engineers. Bellingham, Wash: SPIE, 2008.

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12

Nunzi, Jean-Michel. Linear and nonlinear optics of organic materials XI: 21-22 August 2011, San Diego, California, United States. Bellingham, Wash: SPIE, 2011.

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13

(Society), SPIE, ed. Linear and nonlinear optics of organic materials IX: 2 and 4-5 August 2009, San Diego, California, United States. Bellingham, Wash: SPIE, 2009.

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14

Eich, Manfred. Linear and nonlinear optics of organic materials X: 1-2 and 4 August 2010, San Diego, California, United States. Edited by SPIE (Society). Bellingham, Wash: SPIE, 2010.

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15

Foulon, Jean-Dominique F. Structures of redox-active molybdenum and tungsten mononitrosyl complexes of potential interest as materials exhibiting, non-linear optical properties. Birmingham: University of Birmingham, 1990.

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16

Fonseca, Carlos M. da. A panorama of mathematics: Pure and applied : Conference on Mathematics and Its Applications, November 14-17, 2014, Kuwait University, Safat, Kuwait. Providence, Rhode Island: American Mathematical Society, 2016.

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17

Schurz, Henri, Philip J. Feinsilver, Gregory Budzban, and Harry Randolph Hughes. Probability on algebraic and geometric structures: International research conference in honor of Philip Feinsilver, Salah-Eldin A. Mohammed, and Arunava Mukherjea, June 5-7, 2014, Southern Illinois University, Carbondale, Illinois. Edited by Mohammed Salah-Eldin 1946- and Mukherjea Arunava 1941-. Providence, Rhode Island: American Mathematical Society, 2016.

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18

1943-, Gossez J. P., and Bonheure Denis, eds. Nonlinear elliptic partial differential equations: Workshop in celebration of Jean-Pierre Gossez's 65th birthday, September 2-4, 2009, Université libre de Bruxelles, Belgium. Providence, R.I: American Mathematical Society, 2011.

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19

Wagniere, Georges H. Linear and Nonlinear Optical Properties of Molecules. John Wiley & Sons Ltd (Import), 1993.

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20

Kalt, Heinz, and Claus F. Klingshirn. Semiconductor Optics 1: Linear Optical Properties of Semiconductors. Springer, 2019.

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21

1957-, Lakhtakia A., ed. Selected papers on linear optical composite materials. Bellingham, Wash., USA: SPIE Optical Engineering Press, 1996.

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22

Pereira, Suresh. Linear and nonlinear optical properties of artificially structured materials. 2001.

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23

Norwood, Robert A. Linear and Nonlinear Optics of Organic Materials 6. Society of Photo Optical, 2006.

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24

Hughes, James L. P. Linear and nonlinear optical properties of semiconductors: theory and calculations. 1998.

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25

G, Papadopoulos Manthos, Sadlej Andrzej Jerzy, and Leszczynski Jerzy 1949-, eds. Non-linear optical properties of matter: From molecules to condensed phases. Dordrecht: Springer, 2006.

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26

Sahimi, Muhammad. Heterogeneous Materials I: Linear Transport and Optical Properties (Interdisciplinary Applied Mathematics). Springer, 2003.

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27

Leszczynski, Jerzy, Manthos G. Papadopoulos, and Andrzej J. Sadlej. Non-Linear Optical Properties of Matter: From molecules to condensed phases. Springer, 2010.

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28

A, Norwood Robert, Eich Manfred, Kuzyk Mark G. 1958-, and Society of Photo-optical Instrumentation Engineers., eds. Linear and nonlinear optics of organic materials IV: 2-3 August, 2004, Denver, Colorado, USA. Bellingham, Wash: SPIE, 2004.

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29

Manfred, Eich, Kuzyk Mark G. 1958-, and Society of Photo-optical Instrumentation Engineers., eds. Linear and nonlinear optics of organic materials II: 9-11 July, 2002, Seattle, Washington, USA. Bellingham, Wash: SPIE, 2002.

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30

J, McGilp, Weaire D. L, and Patterson C. H. 1961-, eds. Epioptics: Linear and nonlinear optical spectroscopy of surfaces and interfaces. Berlin: Springer, 1995.

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31

A, Norwood Robert, Eich Manfred, Nunzi Jean-Michel, and Society of Photo-optical Instrumentation Engineers., eds. Linear and nonlinear optics of organic materials VI: 15-17 August, 2006, San Diego, California, USA. Bellingham, Wash: SPIE, 2006.

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32

Linear and Nonlinear Optics of Organic Materials VII: 28-30 August 2007, San Diego, California, USA. SPIE, 2007.

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33

Eich, Manfred. Linear and Nonlinear Optics of Organic Materials 5: 2-4 August, 2005, San Diego Ca, USA. SPIE-International Society for Optical Engine, 2005.

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34

Manfred, Eich, and Society of Photo-optical Instrumentation Engineers., eds. Linear, nonlinear, and power-limiting organics: 31 July-3 August 2000, San Diego, USA. Bellingham, Wash., USA: SPIE, 2000.

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35

Taliani, C., and Z. V. Vardeny. Synthetic Metals for Non-Linear Optics and Electronics. European Research Society Symposia Proceedings, Volume 35). North-Holland, 1993.

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36

1957-, Lakhtakia A., Dewar Graeme, McCall Martin W, and Society of Photo-optical Instrumentation Engineers., eds. Complex mediums III: Beyond linear isotropic dielectrics : 8-10 July 2002, Seattle, [Washington] USA. Bellingham, Washington: SPIE, 2002.

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37

(Editor), Manthos G. Papadopoulos, Andrzej J. Sadlej (Editor), and Jerzy Leszczynski (Editor), eds. Non-Linear Optical Properties of Matter (Challenges and Advances in Computational Chemistry and Physics). Springer, 2006.

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38

J, Hodgkinson Ian, Lakhtakia A. 1957-, Weiglhofer Werner S, and Society of Photo-optical Instrumentation Engineers., eds. Complex mediums II: Beyond linear isotropic dielectrics : 30 July-1 August 2001, San Diego, USA. Bellingham, Wash., USA: SPIE, 2001.

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39

Zagone, Robin L. Linear and nonlinear optical investigation of films: I. Formalism for time resolved multiphoton processes. II. Detection of solid water phase transitions on Si-SiO₂ III. Wave guided CARS spectroscopy. 1995.

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40

Manfred, Eich, Kuzyk Mark G. 1958-, and Society of Photo-optical Instrumentation Engineers., eds. Linear and nonlinear optics of organic materials: 1-2 August 2001, San Diego, USA. Bellingham, Wash., USA: SPIE, 2001.

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41

Graeme, Dewar, McCall Martin W, and Society of Photo-optical Instrumentation Engineers., eds. Complex mediums IV: Beyond linear isotropic dielectrics : 4-5 August, 2003, San Diego, California, USA. Bellingham, Wash: SPIE, 2003.

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42

(Editor), J. McGilp, D. Weaire (Editor), and C. H. Patterson (Editor), eds. Epioptics: Linear and Nonlinear Optical Spectroscopy of Surfaces and Interfaces (Esprit Basic Research Series). Springer-Verlag Telos, 1995.

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43

Newnham, Robert E. Properties of Materials. Oxford University Press, 2004. http://dx.doi.org/10.1093/oso/9780198520757.001.0001.

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Crystals are sometimes called 'Flowers of the Mineral Kingdom'. In addition to their great beauty, crystals and other textured materials are enormously useful in electronics, optics, acoustics and many other engineering applications. This richly illustrated text describes the underlying principles of crystal physics and chemistry, covering a wide range of topics and illustrating numerous applications in many fields of engineering using the most important materials today. Tensors, matrices, symmetry and structure-property relationships form the main subjects of the book. While tensors and matrices provide the mathematical framework for understanding anisotropy, on which the physical and chemical properties of crystals and textured materials often depend, atomistic arguments are also needed to quantify the property coefficients in various directions. The atomistic arguments are partly based on symmetry and partly on the basic physics and chemistry of materials. After introducing the point groups appropriate for single crystals, textured materials and ordered magnetic structures, the directional properties of many different materials are described: linear and nonlinear elasticity, piezoelectricity and electrostriction, magnetic phenomena, diffusion and other transport properties, and both primary and secondary ferroic behavior. With crystal optics (its roots in classical mineralogy) having become an important component of the information age, nonlinear optics is described along with the piexo-optics, magneto-optics, and analogous linear and nonlinear acoustic wave phenomena. Enantiomorphism, optical activity, and chemical anisotropy are discussed in the final chapters of the book.
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44

Linear and nonlinear optics of organic materials III: 4-6 August 2003, San Diego, California, USA. Bellingham, WA: SPIE, 2004.

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45

1958-, Kuzyk Mark G., Eich Manfred, Norwood Robert A, and Society of Photo-optical Instrumentation Engineers., eds. Linear and nonlinear optics of organic materials III: 4-6 August, 2003, San Diego, California, USA. Bellingham, Wash: SPIE, 2003.

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46

Kavokin, Alexey V., Jeremy J. Baumberg, Guillaume Malpuech, and Fabrice P. Laussy. Weak-coupling microcavities. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198782995.003.0006.

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In this chapter we address the optical properties of microcavities in the weak-coupling regime and review the emission of light from microcavities in the linear regime. We present a derivation of the Purcell effect and stimulated emission of radiation by microcavities, and consider how this develops towards lasing. Finally, we briefly consider nonlinear properties of weakly coupled semiconductor microcavities. The functionality of vertical-cavity surface-emitting lasers (VCSELs) is also described.
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47

Kavokin, Alexey V., Jeremy J. Baumberg, Guillaume Malpuech, and Fabrice P. Laussy. Strong coupling: resonant effects. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198782995.003.0007.

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This chapter presents experimental studies performed on planar semiconductor microcavities in the strong-coupling regime. The first section reviews linear experiments performed in the 1990s that evidence the linear optical properties of cavity exciton-polaritons. The chapter is then focused on experimental and theoretical studies of resonantly excited microcavity emission. We mainly describe experimental configuations in which stimulated scattering was observed due to formation of a dynamical condensate of polaritons. Pump-probe and cw experiments are described in addition. Dressing of the polariton dispersion and bistability of the polariton system due to inter-condensate interactions are discussed. The semiclassical and the quantum theories of these effects are presented and their results analysed. The potential for realization of devices is also discussed.
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48

Furst, Eric M., and Todd M. Squires. Active microrheology. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199655205.003.0007.

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Active microrheology uses external forces (most typically magnetic or optical) to force microrheological probes into motion. These techniques short-circuit the Einstein component of passive microrheology. Active microrheology provides an additional handle to probe material properties, and has been used both to extend the range of materials amenable to microrheological analysis, and to examine material properties that are inaccessible to passive microrheology. Three main topics are presented: the use of active microrheology to extend the range of passive microrheology, while maintaining many of the advantages (small sample size, wide frequency range, etc.); its use to complement passive microrheology in active systems, which convert chemical fuel to mechanical work, in order to elucidate the power provided by molecular motors, for instance; and its application (and potential limitations) to investigate the non-linear response properties of materials, including shear thinning and yielding.
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49

Gillam, Barbara. An Analysis of Theoretical Approaches to Geometrical-Optical Illusions. Oxford University Press, 2017. http://dx.doi.org/10.1093/acprof:oso/9780199794607.003.0004.

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The geometrical optical illusions, such as the Müller-Lyer and the Poggendorff, are simple line drawings, which demonstrate errors as large as 25% when people are asked to match their properties such as size, angles, and line collinearity. They have been tantalizing people for at least 150 years and are still not really understood. Illusion figures have been used to probe the consistency of different perceptual properties and also of perception and action with implications for the theory of two visual systems. Explanations of geometrical illusions tend to invoke either physiological processes or the functional role illusion responses may have when viewing a 3D scene. This chapter examines all of these theoretical issues, discussing evidence for and against the major theories.
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50

Back, Kerry E. Portfolio Choice. Oxford University Press, 2017. http://dx.doi.org/10.1093/acprof:oso/9780190241148.003.0002.

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The portfolio choice model is introduced, and the first‐order condition is derived. Properties of the demand for a single risky asset are derived from second‐order risk aversion and decreasing absolute risk aversion. Optimal investments are independent of initial wealth for investors with constant absolute risk aversion. Optimal investments are affine functions of initial wealth for investors iwth linear risk tolerance. The optimal portfolio for an investor with constant absolute risk aversion is derived when asset returns are normally distributed. Investors with quadratic utility have mean‐variance preferences, and investors have mean‐variance preferences when returns are elliptically distributed.
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