RÉFÉRENCESMott, N.F. (1949). The basis of the theory of electron m<strong>et</strong>als, with special reference to th<strong>et</strong>ransition m<strong>et</strong>als. Proc. Phys. Soc. London, Ser. A, 62, 416+. 25Mott, N.F. (1961). The transition to the m<strong>et</strong>allic state. Philosophical Magazine, 6, 287–309. 14Mott, N.F. (1966). The electrical properties of liquid mercury. Philosophical Magazine, 13,989–1014. 16Mott, N.F. (1967). Electrons in disor<strong>de</strong>red structures. Advances in Physics, 16, 49–144. 3Mott, N.F. & Davis, E.A. (1979a). Electronic Processes in Non-Crystalline Materials (Monographson Physics). Oxford University Press, USA, 2nd edn. 2tel-00589730, version 1 - 1 May 2011Mott, N.F. & Davis, E.A. (1979b). Electronic Processes in Non-Crystalline Materials (Monographson Physics). Oxford University Press, USA, 2nd edn. 35Muranoi, T. & Furukoshi, M. (1978). Properties of stannic oxi<strong>de</strong> thin films produced fromthe sncl4-h2o and sncl4-h2o2 reaction systems. Thin Solid Films, 48, 309–318. 102, 103Muraoka, Y., Takubo, N. & Hiroi, Z. (2009). Photoinduced conductivity in tin dioxi<strong>de</strong> thinfilms. Journal of Applied Physics, 105, 103702+. 102, 103, 105, 164, 165Murthy, O.V.S.N. & Venkataraman, V. (2009). A closed-cycle refrigerator based pulsedmagn<strong>et</strong> system. International Journal of Mo<strong>de</strong>rn Physics B (IJMPB), 23, 3024–3028. 118Myasnikov, A.V. & Sadovskii, M.V. (1982). Self-consistent theory of localization in 2d4 dimensionspaces. Fiz. Tverd. Te<strong>la</strong> [Sov. Phys.-Solid State 24, 2033 (1982)], 24, 3569–3574. 163Nagasawa, M. & Shionoya, S. (1971a). Electrical conductivity of sno° 2° single crystals atvery low temperatures. Journal of the Physical Soci<strong>et</strong>y of Japan, 30, 1213–1214. 9, 105Nagasawa, M. & Shionoya, S. (1971b). Properties of oxidized sno° 2° single crystals. JapaneseJournal of Applied Physics, 10, 727–731. 9Nasser, S. (1999). Characterization of boron-doped tin oxi<strong>de</strong> thin films. Thin Solid Films, 342,47–51. 102, 105Nguyen, V.L., Spivak, B.Z. & Shklovskii, B.I. (1985a). Aaronov-Bohm oscil<strong>la</strong>tions withnormal and superconducting flux quanta in hopping conductivity. L<strong>et</strong>ters to Journal of Experimenta<strong>la</strong>nd Theor<strong>et</strong>ical Physics [Pis’ma Zh. Eksp. Teor. Fiz. 41, 35 ], 41, 42+. 48, 49, 52,139Nguyen, V.L., Spivak, B.Z. & Shklovskii, B.I. (1985b). Tunnel hopping in disor<strong>de</strong>red systems.Journal of Experimental and Theor<strong>et</strong>ical Physics [Zh. Exp. Teor. Fiz. 89, 1770-1784], 62,1021+. 48, 49, 52, 139190
RÉFÉRENCESNiimi, Y., Baines, Y., Capron, T., Mailly, D., Lo, F.Y., Wieck, A.D., Meunier, T., Saminadayar,L. & Bäuerle, C. (2010). Quantum coherence at low temperatures in mesoscopicsystems : Effect of disor<strong>de</strong>r. Physical Review B, 81, 245306+. 139Noks, R.S. & Gold, A. (1964). Symm<strong>et</strong>ry in the Solid State. W.A. Benjamin, Inc., New York,Amsterdam. 15Nozieres, P. & Pines, D. (1999). Theory Of Quantum Liquids (Advanced Books C<strong>la</strong>ssics) (v.1 & 2). Westview Press. 58, 59, 60, 61tel-00589730, version 1 - 1 May 2011Olshan<strong>et</strong>skii, E.B., Renard, V., Kvon, Z.D., Gornyi, I.V., Toropov, A.I. & Portal,J.C. (2006). Interaction effects in the transport and magn<strong>et</strong>otransport of two-dimensional electronsin AlGaAs/GaAs and Si/SiGe h<strong>et</strong>erojunctions. Physics-Uspekhi [Uspekhi Fiz. Nauk 176,222-227 (2006)], 49, 211–216. 94, 155, 156Ovadyahu, Z. (1986). Anisotropic magn<strong>et</strong>oresistance in a Fermi g<strong>la</strong>ss. Physical Review B, 33,6552–6554. 3Ovadyahu, Z. & Imry, Y. (1983). On the role of the corre<strong>la</strong>tion length near the ons<strong>et</strong> of nonm<strong>et</strong>allicconduction. Journal of Physics C : Solid State Physics, 16, L471–L476. 3Pan, Z.W., Dai, Z.R. & Wang, Z.L. (2001). Nanobelts of Semiconducting Oxi<strong>de</strong>s. Science,291, 1947–1949. 106Patil, P. (2003). Effect of substrate temperature on structural, electrical and optical propertiesof sprayed tin oxi<strong>de</strong> (sno2) thin films. Ceramics International, 29, 725–734. 103Polyakov, D.G. & Samokhin, K.V. (1998). Dynamical Scaling at the Quantum Hall Transition: Coulomb Blocka<strong>de</strong> versus Phase Breaking. Physical Review L<strong>et</strong>ters, 80, 1509–1512.23Pudalov (1998a). Logarithmic temperature <strong>de</strong>pen<strong>de</strong>nce of conductivity of the two-dimensionalm<strong>et</strong>al. JETP L<strong>et</strong>ters, 68, 497+. 5Pudalov (1998b). M<strong>et</strong>al-insu<strong>la</strong>tor transition in two dimensions. Physica E, 3, 79–88. 2, 5Pudalov, V.M. (2006). M<strong>et</strong>al&ndash ;insu<strong>la</strong>tor transitions and re<strong>la</strong>ted phenomena in a stronglycorre<strong>la</strong>ted two-dimensional electron system. Physics-Uspekhi, 49, 203–208. 2, 4, 5Punnoose, A. & Finkel’stein, A.M. (2005). M<strong>et</strong>al-insu<strong>la</strong>tor transition in disor<strong>de</strong>red twodimensionalelectron systems. Science, 310, 289–291. 133Raimes, S. (1972). Many-electron theory. North-Hol<strong>la</strong>nd Pub. Co. 62Ramakrishnan, T.V. (1995). M<strong>et</strong>al-Insu<strong>la</strong>tor Transitions - Whither Theory?, chap. 1, 293–307.CRC Press, 2nd edn. 7, 26, 48191
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- Page 207: RÉFÉRENCESMessiah (1999). Mécani
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- Page 213 and 214: RÉFÉRENCES(y.) Bogoliubov, N.N. &