Couches minces d'oxyde d'Ã©tain: la localisation faible et les effets de ...

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RÉFÉRENCESBatzill, M. & Diebold, U. (2005). The surface and materials science of tin oxide. Progress inSurface Science, 79, 47–154. 10, 95, 97, 106Belitz, D. & Kirkpatrick, T.R. (1994). The anderson-mott transition. Reviews of ModernPhysics, 66, 261–380. 15, 17, 19, 20, 21, 22, 26Belitz, D. & Kirkpatrick, T.R. (1998). Possible triplet superconductivity in mosfets. PhysicalReview B, 58, 8214–8217. 5Bergermayer, W. & Tanaka, I. (2004). Reduced sno[sub 2] surfaces by first-principles calculations.Applied Physics Letters, 84, 909–911. 97Bergmann, G. (1982a). Measurement of the magnetic scattering time by weak localization. Phys.Rev. Lett., 49, 162–164. 144tel-00589730, version 1 - 1 May 2011Bergmann, G. (1982b). Quantitative analysis of weak localization in thin mg films by magnetoresistancemeasurements. Phys. Rev. B, 25, 2937–2939. 144Bishop, D.J., Tsui, D.C. & Dynes, R.C. (1980). Nonmetallic conduction in electron inversionlayers at low temperatures. Physical Review Letters, 44, 1153–1156. 5Bishop, D.J., Dynes, R.C. & Tsui, D.C. (1982). Magnetoresistance in si metal-oxidesemiconductorfield-effect transitors : Evidence of weak localization and correlation. PhysicalReview B, 26, 773–779. 5Borzdov, V. & Petrovich, T. (1997). Monte carlo simulation of the low-temperature mobilityof two-dimensional electrons in a silicon inversion layer. Semiconductors, 31, 72–75. 5Brenig, W., Paalanen, M.A., Hebard, A.F. & Wölfle, P. (1986). Magnetoconductanceof thin-film superconductors near critical disorder. Physical Review B, 33, 1691–1699. 90Brézin, E. (1980). Generalized non-linear -models with gauge invariance. Nuclear Physics B,165, 528–544. 22Brézin, E., Justin, J.Z. & Le Guillou, J.C. (1976). Renormalization of the nonlinear σ modelin 2 + ǫ dimensions. Physical Review D, 14, 2615–2621. 21Çetin Ki li & Zunger, A. (2002). Origins of coexistence of conductivity and transparency insno2. Physical Review Letters, 88, 095501+. 9, 97, 102Chacko, S., Philip, N.S. & Vaidyan, V.K. (2007). Effect of substrate temperature on structural,optical and electrical properties of spray pyrolytically grown nanocrystalline sno2 thinfilms. physica status solidi (a), 204, 3305–3315. 102Chacko, S., Philip, N., Gopchandran, K., Koshy, P. & Vaidyan, V. (2008a). Nanostructuraland surface morphological evolution of chemically sprayed SnO2 thin films. Applied SurfaceScience, 254, 2179–2186. 102182
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THÈSEtel-00589730, version 1 - 1 M
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tel-00589730, version 1 - 1 May 201
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Table des matièresTable des figure
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TABLE DES FIGURES7.5 Dépendances d
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TABLE DES FIGUREStel-00589730, vers
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LISTE DES TABLEAUXtel-00589730, ver
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1. INTRODUCTIONtel-00589730, versio
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1. INTRODUCTION(ρ - concentration
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2. PRÉSENTATION DE L’ÉTUDESigna
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2. PRÉSENTATION DE L’ÉTUDEtel-0
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3. MÉCANISMES DE TRANSPORT DE CHAR
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4. LES VOIES DE LA DIFFUSION DES PO
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4.1 L’interaction entre les quasi
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4.2 Quantification et l’Hamiltoni
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4.3 La classification des voies de
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4.4 Les effets de l’interaction
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4.5 Conductivité en présence de l
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5.1 Les couches polycristallines de
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6.2 Résistance du côté métalliq
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Page 197 and 198: RéférencesAbrahams, E. & Ramakris
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Page 207 and 208: RÉFÉRENCESMessiah (1999). Mécani
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Page 213 and 214: RÉFÉRENCES(y.) Bogoliubov, N.N. &
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