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1. Baibarac M, Gomez-Romero P (2006) Nanocomposites based on conducting polymers and carbon nanotubes: from fancy materials to functional applications . Journal of Nanoscience and Nanotechnology 6:289-302

2. Green MA (2006) Synthesizing semiconducting material using silicon - a nanostructured composite of silicon quantum dots in an amorphous matrix. In: Bandyopadhyay S, Berndt CC, Rizkalla S, Gowripalan N, Matisons J, Zeng Q (eds) ACUN-5 International Composites Conference: Developments in Composites: Advanced, Infrastructural, Natural and Nanocomposites Sydney, pp 513-518

3 . Sanchez C , Julian B , Belleville P, Popall M (2005) Applications of hybrid organic-inorganic nanocomposites. Journal of Materials Chemistry 15:3559-3592

4. Amato G, Borini S, Rossi AM, Boarino L, Rocchia M (2005) Si/SiO2 nanocomposite by CVD infiltration of porous SiO2. Physica Status Solidi A-Applications and Materials Science 202:1529-1532

5. Baibarac M, Baltog I, Lefrant S, Mevellec JY, Chauvet O (2003) Polyaniline and carbon nano-tubes based composites containing whole units and fragments of nanotubes. Chemistry of Materials 15:4149-4156

6. Besenhard JO, Hess M, Komenda P (1990) Dimensionally stable Li-alloy electrodes for secondary batteries. Solid State Ionics 40-41:525-529

7. Bhattacharya A, Ganguly KM, De A, Sarkar S (1996) A new conducting nanocomposite -PPy-zirconium(IV) oxide. Materials Research Bulletin 31:527-530

8. Bhattacharya SK, Tummala RR (2001) Integral passives for next generation of electronic packaging: application of epoxy/ceramic nanocomposites as integral capacitors. Microelectronics Journal 32:11-19

9. Caseri WR (2006) Nanocomposites of polymers and inorganic particles: preparation, structure and properties. Materials Science and Technology 22:807-817

10. Siwick BJ, Kalinina O, Kumacheva E, Dwayne Miller RJ, Noolandi J (2001) Polymeric nanostructured material for high-density three-dimensional optical memory storage. Journal of Applied Physics 90:5328-5334

11. Lockwood DJ, Lu ZH, Baribeau JM (1996) Quantum confined luminescence in Si/SiO2 super-lattices. Physical Review Letters 76:539-541

12. (a) Kim DS, Lee T, Geckeler KE (2006) Hole-doped single-walled carbon nanotubes: ornamenting with gold nanoparticles in water. Angewandte Chemie (International ed. in English) 45: 104-107

12. (b) Mahima S, Chaki NK, Sharma J, Kakade BA, Pasricha R, Rao AM, Vijayamohanan K (2006) Electrochemical organization of monolayer protected gold nanoclusters on singlewalled carbon nanotubes: Significantly enhanced double layer capacitance. Journal of Nanoscience and Nanotechnology 6:1387-1391

13. Merhari L, Belorgeot C, Moliton JP (1990) Etch rate modeling for ion-irradiated nitrocellulose. Applied Physics Letters 57:2785-2787

14. Merhari L, Moliton JP, Belorgeot C (1990) Fourier-transform infrared study of ion irradiated nitrocellulose. Journal of Applied Physics 68:4837-4845

15. Merhari L, Lehue C, Belorgeot C, Bahna Z (1991) Ion-implantation profile modeling of nitrocellulose coated substrates. Applied Physics Letters 59:2856-2858

16. Merhari L, Belorgeot C, Moliton JP (1991) Ion irradiation induced effects in polyamidoimide. Journal of Vacuum Science & Technology B 9:2511-2522

17. Merhari L, Belorgeot C, Quintard P (1994) Helium ion-irradiated polyamidoimide films - a ft-ir and raman follow-up. Journal of Materials Science Letters 13:286-288

18. Merhari L, Gonsalves KE, Hu Y, He W, Huang WS, Angelopoulos M, Bruenger WH, Dzionk C, Torkler M (2002) Nanocomposite resist systems for next generation lithography. Microelectronic Engineering 63:391-403

19. Ogitani S, Bidstrup-Allen SA, Kohl PA (2000) Factors influencing the permittivity of polymer/ ceramic composites for embedded capacitors. IEEE Transactions on Advanced Packaging 23:313-322

20. Ago H, Petritsch K, Shaffer MSP, Windle AH, Friend RH (1999) Composites ofcarbon nanotubes and conjugated polymers for photovoltaic devices. Advanced Materials 11:1281-1285

21. Bakueva L, Musikhin S, Sargent EH, Schulz S (2003) Fabrication and investigation of nanocomposites of conducting polymers and GaSb nanocrystals. Surface Science 532:828-831

22. http://www.intel.com/technology/silicon/65nm_technology.htm.

23 . Amos SW, James MR (1999) Principles of Transistor Circuits . Butterworth-Heinemann , Oxford

24. Horowitz, Paul, Hill (1989) The Art of Electronics. Cambridge University Press, Winfield 25 . Warnes L (1998) Analogue and Digital Electronics . Macmillan , New York 26. Brick CM, Ouchi Y, Chujo Y, Laine RM (2005) Robust polyaromatic octasilsesquioxanes from polybromophenylsilsesquioxanes, BrxOPS, via Suzuki coupling. Macromolecules 38:4661-4665

27 . Kumar S , Pimparkar N , Murthy JY, Alam MA (2006) Theory of transfer characteristics of nanotube network transistors. Applied Physics Letters 88:123505 (1-3)

28 . Kumar TP, Ramesh R , Lin YY, Fey GTK (2004) Tin-filled carbon nanotubes as insertion anode materials for lithium-ion batteries. Electrochemistry Communications 6:520-525

29. Philip B, Xie JI, Abraham JK, Varadan VK (2004) A new synthetic route to enhance polyaniline assembly on carbon nanotubes in tubular composites. Smart Materials & Structures 13: N105-N108

30. Torsi L, Cioffi N, Di Franco C, Sabbatini L, Zambonin PG, Bleve-Zacheo T (2001) Organic thin film transistors: from active materials to novel applications. Solid-State Electronics 45:1479-1485

31 . Yao KJ , Song M , Hourston DJ , Luo DZ (2002) Polymer/layered clay nanocomposites: 2

polyurethane nanocomposites. Polymer 43:1017-1020

32 . Yao ZL , Braidy N , Botton GA , Adronov A (2003) Polymerization from the surface of single walled carbon nanotubes - preparation and characterization of nanocomposites. Journal of the American Chemical Society 125:16015-16024

33 . Ree M , Goh WH , Kim Y (1995) Thin-films of organic polymer composites with inorganic aerogels as dielectric materials - polymer-chain orientation and properties. Polymer Bulletin 35:215-222

34. Ree M, Shin TJ, Lee SW (2001) Fully rod-like aromatic polyimides: Structure, properties, and chemical modifications. Korea Polymer Journal 9:1-19

35. Ree MH, Yoon JW, Heo KY (2006) Imprinting well-controlled closed-nanopores in spin-on polymeric dielectric thin films. Journal of Materials Chemistry 16:685-697

36. Kang S, Leblebici Y (2002) CMOS Digital Integrated Circuits Analysis & Design. McGraw-Hill, New Tork

37. Mead C, Conway L (1980) Introduction to VLSI systems. Addison Wesley, Reading, MA

38. Hodges DA, Jackson HG, Saleh R (2003) Analysis and Design of Digital Integrated Circuits. McGraw-Hill , New York

39 . Rbaey JM , Chandrakasan A , Nikolic B (1996) Digital Integrated Circuits . Prentice Hall , Englewood Cliffs, NJ

40. Huelsman LP (1972) Basic Circuit Theory with Digital Computations. Prentice-Hall, Englewood Cliffs, NJ

41. Maini AK (1998) Electronic Projects for Beginners. Pustak Mahal, India

42. Zorpette G (2005) Super charged: a tiny South Korean company is out to make capacitors powerful enough to propel the next generation of hybrid-electric cars. IEEE Spectrum 42:32 -37

43. Carpick RW, Sasaki DY, Marcus MS, Eriksson MA, Burns AR (2004) Polydiacetylene films: a review of recent investigations into chromogenic transitions and nanomechanical properties. Journal of Physics-Condensed Matter 16:R679-R697

44 . Murugaraj P, Mainwaring D , Mora-Huertas N (2006) Thermistor behaviour in a semiconducting polymer-nanoparticle composite film. Journal of Physics D-Applied Physics 39:2072-2078 45. Chen WX, Lee JY, Liu ZL (2002) Electrochemical lithiation and de-lithiation of carbon nanotube-Sn2Sb nanocomposites. Electrochemistry Communications 4:260-265 46 . batteryuniversity.com.

47. http://en.wikipedia.org.

48. Dang ZM, Wang HY, Zhang YH, Qi JQ (2005) Morphology and dielectric property ofhomog-enous BaTiO3/PVDF nanocomposites prepared via the natural adsorption action of nanosized BaTiO3. Macromolecular Rapid Communications 26:1185-1189

49. Das D, Chakravorty D (2001) Alternating current conductivity of the interfacial phase in copper oxide-silica gel nanocomposites. Journal of Materials Research 16:1047-1051

50 . Gonon P, Boudefel A (2006) Electrical properties of epoxy/silver nanocomposites . Journal of Applied Physics 99

51. Li L, Takahashi A, Hao JJ, Kikuchi R, Hayakawa T, Tsurumi TA, Kakimoto MA (2005) Novel polymer-ceramic nanocomposite based on new concepts for embedded capacitor application (I). IEEE Transactions on Components and Packaging Technologies 28:754-759

52 . Misman O , Bhattacharya SK , Erbil A , Tummala RR (2000) PWB compatible high value integral capacitors by MOCVD. Journal of Materials Science-Materials in Electronics 11:657-660

53 . Pothukuchi S , Li Y, Wong CP (2004) Development of a novel polymer-metal nanocomposite obtained through the route of in situ reduction for integral capacitor application. Journal of Applied Polymer Science 93:1531-1538

54 . Rao Y, Ogitani S , Kohl P, Wong CP (2002) Novel polymer-ceramic nanocomposite based on high dielectric constant epoxy formula for embedded capacitor application. Journal of Applied Polymer Science 83:1084-1090

55 . Jillek W, Yung WKC (2005) Embedded components in printed circuit boards: a processing technology review. International Journal of Advanced Manufacturing Technology 25 : 350 - 360

56 . Tummala RR , Rymaszewski EJ , Klopfenstein AG (1999) Microelectronics Packaging

Handbook . Kluwer, Norwell

57. Clearfield HM, Wijeyesekera S, Logan EA, Luu A, Gieser D, Lin CM, Jing J (1998) Integrated passive devices using Al/BCB thin films. In Third Advanced Technology on Workshop Integrated Passives Technol, Denver

58. Cho YH, Park JM, Park YH (2004) Preparation and properties of polyimides having highly flexible linkages and their nanocomposites with organoclays. Macromolecular Research 12:38-45

59. Ramesh S, Shutzberg BA, Huang C, Gao J, Giannelis EP (2003) Dielectric nanocomposites for integral thin film capacitors: Materials design, fabrication, and integration issues. IEEE Transactions on Advanced Packaging 26:17-24

60. Rao Y, Wong CP (2004) Material characterization of a high-dielectric-constant polymer-ceramic composite for embedded capacitor for RF applications. Journal of Applied Polymer Science 92:2228-2231

61. Godovski, Yu D (1995) Advances in Polymer Science 119:79-122

62. www.3m.com/us/electronics_mfg/microelectronic_packaging/materials.

63. Rao Y, Yue J, Wong CP (2001) High K polymer-ceramic nano-composite development, characterization and modeling for embedded capacitor RF application. Proceedings of the Electronic Components Technology Conference, 1408-1419

64. Kuo DH, Chang CC, Su TY, Wang WK, Lin BY (2004) Dielectric properties ofthree ceramic/ epoxy composites. Materials Chemistry and Physics 85:201-206

65. Bidstrup-Allen SA, Kohl PA (2002) IEEE Transactions on Advanced Packaging 23:313

66 . Vrejoiu I , Pedarnig JD , Dinescu M , Bauer-Gogonea S , Bauerle D (2002) Flexible ceramic-polymer composite films with temperature-insensitive and tunable dielectric permittivity. Applied Physics A-Materials Science & Processing 74:407-409

67. Xu J, Bhattacharya S, Moon K, Lu J, Englert B, Wong CP, Pramanik P (2006) Large Area Processable High k Nanocomposite-Based Embedded Capacitors. IEEE Electronic Components and Technology Proceedings 56:1520-1532

68. Bai Y, Cheng ZY, Bharti V, Xu HS, Zhang QM (2000) High-dielectric-constant ceramic-powder polymer composites. Applied Physics Letters 76:3804-3806

69 . Chiteme C , McLachlan DS (2003) ac and dc conductivity, magnetoresistance, and scaling in cellular percolation systems. Physical Review B 67(2), pp. 024206.1-024206.18

70 . Desurvire E (1994) Erbium Doped Fiber Amplifiers . Wiley, New York

71. Kozeki M (2002) The condensor film and its property. Proceeding of Eighth JIEP Microfabrication Research Report, 31

72 . NEMI (1998) National Electronics Manufacturing Technology Roadmap . National Electronics Manufacturing Initiative, Herndon

73. Chahal P, Tummala R, Allen M, Swaminathan M (1999) IEEE Transactions on Components, Packaging and Manufacturing Technology B21:184

74. Rao Y, Wong CP (2002) Proceedings of the Eight International Symposium on Advanced Packaging Materials, 243

75. Bergman DJ, Stroud D (1992) Physical properties of macroscopically inhomogenous media. Solid State Physics 46:147

76. Clerc JP, Giraud G, Laugier JM, Luck JM (1990) Advances in Physics 39:191

77. Choi SH, Kim JS, Yoon YS (2004) Fabrication and characterization of SnO2-RuO2 composite anode thin film for lithium ion batteries. Electrochimica Acta 50:547-552

78. Pecharroman C, Esteban-Betegon F, Bartolome JF, Lopez-Esteban S, Moya JS (2001) New percolative BaTiO3-Ni composites with a high and frequency-independent dielectric constant (epsilon(r) approximate to 80,000). Advanced Materials 13:1541-1544

79. Dang ZM, Shen Y, Nan CW (2002) Dielectric behavior of three-phase percolative Ni-BaTiO3/ polyvinylidene fluoride composites. Applied Physics Letters 81:4814-4816

80. Chou YC, Jaw TS (1988) Divergence of dielectric-constant near the percolation-threshold. Solid State Communications 67:753-756

81. Chung KT, Sabo A, Pica AP (1982) Electrical permittivity and conductivity of carbon-black polyvinyl-chloride composites. Journal of Applied Physics 53:6867-6879

82. Grannan DM, Garland JC, Tanner DB (1981) Critical-behavior of the dielectric-constant of a random composite near the percolation-threshold. Physical Review Letters 46:375-378

83. Flandin L, Prasse T, Schueler R, Schulte K, Bauhofer W, Cavaille JY (1999) Anomalous percolation transition in carbon-black-epoxy composite materials . Physical Review B 59 : 14349-14355

84. McLachlan DS, Heaney MB (1999) Complex ac conductivity of a carbon black composite as a function of frequency, composition, and temperature. Physical Review B 60:12746-12751

85. Bhattacharyya SK, Basu S, DE SK (1975) Composites Part A-Applied Science and Manufacturing 9 : 177

86 . Luechinger N, Wendelin JS, Bandyopadhyay S, Heness G (2006) Processing, Structure and Electrical Properties of C/Co-Polymer Nanocomposites. Internal Report ETH Zurich/UNSW/ UTS

87. Cho SD, Lee JY, Hyun JG, Paik KW (2004) Study on epoxy/BaTiO3 composite embedded capacitor films (ECFs) for organic substrate applications. Materials Science and Engineering B-Solid State Materials for Advanced Technology 110:233-239

88. Dong LJ, Xiong CX, Chen J, Nan CW (2004) Dielectric behavior of BaTiO3/PVDF nanocomposites in-situ synthesized by the sol-gel method. Journal of Wuhan University of Technology-Materials Science Edition 19:9-11

89. Wang J, Guo ZP, Zhong S, Liu HK, Dou SX (2003) Lead-coated glass fibre mesh grids for lead-acid batteries. Journal of Applied Electrochemistry 33:1057-1061

90. Wang J, Zhong S, Liu HK, Dou SX (2003) Beneficial effects of red lead on non-cured plates for lead-acid batteries. Journal of Power Sources 113:371-375

91. Chen J, Bradhurst DH, Dou SX, Liu HK (1998) Electrode properties of Mg2Ni alloy ball-milled with cobalt powder. Electrochimica Acta 44:353-355

92. Luan B, Liu HK, Dou SX (1997) On the elemental substitutions of titanium-based hydrogen-storage alloy electrodes for rechargeable Ni-MH batteries. Journal of Materials Science 32 : 2629 - 2635

93 . Sadoway DR , Mayes AM (2002) Portable power: advanced rechargeable lithium batteries . Mrs Bulletin 27:590-592

94. Liu HK, Wang GX, Guo ZP, Wang JZ, Konstantinov K (2006) Nanomaterials for lithium-ion rechargeable batteries. Journal of Nanoscience and Nanotechnology 6:1-15

95. Ng SH, Wang J, Konstantinov K, Wexler D, Chen J, Liu HK (2006) Spray pyrolyzed PbO-carbon nanocomposites as anode for lithium-ion batteries. Journal of the Electrochemical Society 153:A787-A793

96. Selvan RK, Kalaiselvi N, Augustin CO, Doh CH, Sanjeeviraja C (2006) CuFe2O4/SnO2 nanocomposites as anodes for Li-ion batteries. Journal of Power Sources 157:522-527

97. Huggins RA (2002) Alternative materials for negative electrodes in lithium systems. Solid State Ionics 152:61-68

98. Winter M, Brodd RJ (2004) What are batteries, fuel cells, and supercapacitors? Chemical Reviews 104:4245-4269

99. Scrosati B (1992) Lithium rocking chair batteries - an old concept. Journal of the Electrochemical Society 139:2776-2781

100. Besenhard JO, Wagner MW, Winter M, Jannakoudakis AD, Jannakoudakis PD, Theodoridou E (1993) Inorganic film-forming electrolyte additives improving the cycling behavior of metallic lithium electrodes and the self-discharge of carbon lithium electrodes. Journal of Power Sources 44:413-420

101. Imanishi N, Kashiwagi H, Ichikawa T, Takeda Y, Yamamoto O, Inagaki M (1993) Chargedischarge characteristics of mesophase-pitch-based carbon-fibers for lithium cells. Journal of the Electrochemical Society 140:315-320

102. Ahn JH, Wang GX, Yao J, Liu HK, Dou SX (2003) Tin-based composite materials as anode materials for Li-ion batteries. Journal of Power Sources 119:45-49

103 . Hibino M , Abe K , Mochizuki M , Miyayama M (2004) Amorphous titanium oxide electrode for high-rate discharge and charge. Journal of Power Sources 126:139-143

104. Poizot P, Laruelle S, Grugeon S, Dupont L, Tarascon J-M (2000) Nature 407:496-499

105 . Sides CR , Martin CR (2005) Nanostructured electrodes and the low-temperature performance of Li-ion batteries. Advanced Materials 17:125-128

106. Cheng XQ, Shi PF (2005) Electroless Cu-plated Ni3Sn4 alloy used as anode material for lithium ion battery. Journal of Alloys and Compounds 391:241-244

107. Kim YU, Lee SI, Lee CK, Sohn HJ (2005) Enhancement of capacity and cycle-life of Sn

P3 (0 <= delta <= 1) anode for lithium secondary batteries . Journal of Power Sources 141:163-166

108. Xie J, Zhao XB, Cao GS, Zhong YD, Zhao MJ, Tu JP (2005) Solvothermal synthesis of nanosized CoSb2 alloy anode for Li-ion batteries. Electrochimica Acta 50:1903-1907

109. Reddy MV, Wannek C, Pecquenard B, Vinatier P, Levasseur A (2003) LiNiVO4-promising thin films for use as anode material in microbatteries. Journal of Power Sources 119:101-105

110. Idota Y, Kubota T, Matsufuji A, Maekawa Y, Miyasaka T (1997) Tin-based amorphous oxide: A high-capacity lithium-ion-storage material. Science 276:1395-1397

111. Nishijima M, Takeda Y, Imanishi N, Yamamota O (1994) Li deintercalation and structural change in the Lithium transition metal nitride Li3FeN2. Journal of Solid State Chemistry 113:205-210

112. Kishore M, Varadaraju UV, Raveau B (2004) Electrochemical performance of LiMSnO (M = Fe, In) phases with ramsdellite structure as anodes for lithium batteries . Journal of Solid State Chemistry 177:3981-3986

113. Kalaiselvi N, Doh CH, Park CW, Moon SI, Yun MS (2004) A novel approach to exploit LiFePO4 compound as an ambient temperature high capacity anode material for rechargeable lithium batteries. Electrochemistry Communications 6:1110-1113

114. Son JT (2004) Novel electrode material for Li ion battery based on polycrystalline LiNbO3. Electrochemistry Communications 6:990-994

115. Chu YQ, Fu ZW, Qin QZ (2004) Cobalt ferrite thin films as anode material for lithium ion batteries. Electrochimica Acta 49:4915-4921

116. Alcantara R, Jaraba M, Lavela P, Tirado JL, Jumas JC, Olivier-Fourcade J (2003) Changes in oxidation state and magnetic order of iron atoms during the electrochemical reaction of lithium with NiFe2O4. Electrochemistry Communications 5:16-21

117. NuLi YN, Qin QZ (2005) Nanocrystalline transition metal ferrite thin films prepared by an electrochemical route for Li-ion batteries . Journal of Power Sources 142 : 292 - 297

118 . NuLi YN , Chu YQ , Qin QZ (2004) Nanocrystalline ZnFe2O4 and Ag-doped ZnFe2O4 films used as new anode materials for Li-ion batteries. Journal of the Electrochemical Society 151:A1077-A1083

119. Sharma N, Shaju KM, Rao GVS, Chowdari BVR (2003) Iron-tin oxides with CaFe2O4 structure as anodes for Li-ion batteries. Journal of Power Sources 124:204-212

120. Idota Y, Mishima M, Miyaki Y, Kubota T, Miyasaki T (1994) Canadian Patent Application 2:134

121. Idota Y, Mishima M (1995) Canadian Patent Application 2:143

122. Brousse T, Retoux R, Herterich U, Schleich DM (1998) Thin-film crystalline SnO2-lithium electrodes. Journal of the Electrochemical Society 145:1-4

123. Courtney IA, McKinnon WR, Dahn JR (1999) On the aggregation of tin in SnO composite glasses caused by the reversible reaction with lithium. Journal of the Electrochemical Society 146:59-68

124. Goward GR, Leroux F, Power WP, Ouvrard G, Dmowski W, Egami T, Nazar LF (1999) On the nature of Li insertion in tin composite oxide glasses. Electrochemical and Solid State Letters 2 : 367 - 370

125. Liu W, Huang X, Wang Z, Li H, Chen L (1998) J. Electrochem. Soc. 145:59

126. Wolfenstine J, Sakamoto J, Huang CK (1998) Tin oxide tin composite anodes for use in Li-ion batteries. Journal of Power Sources 75:181-182

127. Courtney IA, Dahn JR (1997) Electrochemical and in situ X-ray diffraction studies of the reaction of lithium with tin oxide composites. Journal of the Electrochemical Society 144 : 2045 - 2052

128. Cruz M, Hernan L, Morales J, Sanchez L (2002) Spray pyrolysis as a method for preparing PbO coatings amenable to use in lead-acid batteries. Journal of Power Sources 108:35-40

129. Martos M, Morales J, Sanchez L, Ayouchi R, Leinen D, Martin F, Barrado JRR (2001) Electrochemical properties of lead oxide films obtained by spray pyrolysis as negative electrodes for lithium secondary batteries. Electrochimica Acta 46:2939-2948

130. Yang J, Winter M, Besenhard JO (1996) Small particle size multiphase Li-alloy anodes for lithium-ion-batteries. Solid State Ionics 90:281-287

131. Huggins RA (1999) Lithium alloy negative electrodes. Journal of Power Sources 82:13-19

132. Mao O, Turner RL, Courtney IA, Fredericksen BD, Buckett MI, Krause LJ, Dahn JR (1999) Active/inactive nanocomposites as anodes for Li-ion batteries. Electrochemical and Solid State Letters 2:3-5

133. Yang J, Wachtler M, Winter M, Besenhard JO (1999) Sub-microcrystalline Sn and Sn-SnSb powders as lithium storage materials for lithium-ion batteries . Electrochemical and Solid State Letters 2:161-163

134. Li NC, Martin CR (2001) A high-rate, high-capacity, nanostructured Sn-based anode prepared using sol-gel template synthesis. Journal of the Electrochemical Society 148:A164-A170

135. Li NC, Martin CR, Scrosati B (2000) A high-rate, high-capacity, nanostructured tin oxide electrode. Electrochemical and Solid State Letters 3:316-318

136 . Whitehead AH , Elliott JM , Owen JR (1999) Nanostructured tin for use as a negative electrode material in Li-ion batteries. Journal of Power Sources 82:33-38

137. Yang J, Takeda Y, Imanishi N, Yamamoto O (1999) Ultrafine Sn and SnSb014 powders for lithium storage matrices in lithium-ion batteries. Journal of the Electrochemical Society 146:4009-4013

138 . Yang J , Takeda Y, Imanishi N , Ichikawa T, Yamamoto O (1999) Study of the cycling performance of finely dispersed lithium alloy composite electrodes under high Li-utilization. Journal of Power Sources 79:220-224

139. Che GL, Lakshmi BB, Fisher ER, Martin CR (1998) Carbon nanotubule membranes for electrochemical energy storage and production. Nature 393:346-349

140. Dahn JR, Zheng T, Liu YH, Xue JS (1995) Mechanisms for lithium insertion in carbonaceous materials. Science 270:590-593

141. Gao B, Kleinhammes A, Tang XP, Bower C, Fleming L, Wu Y, Zhou O (1999) Electrochemical intercalation of single-walled carbon nanotubes with lithium. Chemical Physics Letters 307:153-157

142. Guo ZP, Zhao ZW, Liu HK, Dou SX (2005) Electrochemical lithiation and de-lithiation of MWNT-Sn/SnNi nanocomposites. Carbon 43:1392-1399

143. Tans SJ, Verschueren ARM, Dekker C (1998) Room-temperature transistor based on a single carbon nanotube. Nature 393:49-52

144. Wang GX, Yao J, Liu HK (2004) Characterization of nanocrystalline Si-MCMB composite anode materials. Electrochemical and Solid State Letters 7:A250-A253

145 . Badway F, Pereira N , Cosandey F, Amatucci GG (2003) Carbon-metal fluoride nanocom-

posites - structure and electrochemistry of FeF3:C. Journal of the Electrochemical Society 150:A1209-A1218

146 . Wang Y, Lee JY (2005) Microwave-assisted synthesis of SnO2-graphite nanocomposites for

Li-ion battery applications. Journal of Power Sources 144:220-225

147 . Fleischauer MD , Topple JM , Dahna JR (2005) Combinatorial investigations of Si-M

(M = Cr plus Ni, Fe, Mn) thin film negative electrode materials. Electrochemical and Solid State Letters 8:A137-A140

148. Li H, Huang XJ, Chen LQ, Wu ZG, Liang Y (1999) Electrochemical and Solid-State Letters 2 : 547

149. http://www.physorg.com/news3061.html.

150. Nalimova VA, Sklovsky DE, Bondarenko GN, Alvergnat-Gaucher H, Bonnamy S, Beguin F (1997) Lithium interaction with carbon nanotubes. Synthetic Metals 88:89-93

151. Claye AS, Fischer JE, Huffman CB, Rinzler AG, Smalley RE (2000) Solid-state electrochemistry of the Li single wall carbon nanotube system. Journal of the Electrochemical Society 147:2845-2852

152. Frackowiak E, Gautier S, Gaucher H, Bonnamy S, Beguin F (1999) Electrochemical storage of lithium multiwalled carbon nanotubes. Carbon 37:61-69

153. Kim I, Kumta PN, Blomgren GE (2000) Si/TiN nanocomposites - novel anode materials for Li-ion batteries. Electrochemical and Solid State Letters 3:493-496

154. Lee KT, Jung YS, Oh SM (2003) Synthesis of tin-encapsulated spherical hollow carbon for anode material in lithium secondary batteries. Journal of the American Chemical Society 125:5652-5653

155. Besenhard JO (1999) Handbook of Battery Materials. Wiley VCH, Weinheim

156. Fu LJ, Liu H, Zhang HP, Li C, Zhang T, Wu YP, Holze R, Wu HQ (2006) Synthesis and electrochemical performance of novel core/shell structured nanocomposites. Electrochemistry Communications 8:1-4

157. Wang GX, Ahn JH, Yao J, Bewlay S, Liu HK (2004) Nanostructured Si-C composite anodes for lithium-ion batteries. Electrochemistry Communications 6:689-692

158. Wang GX, Chen Y, Yang L, Yao J, Needham S, Liu HK, Ahn JH (2005) Journal Power Sources 146 : 487

159. Martos M, Morales J, Sanchez L (2003) Lead-based systems as suitable anode materials for Li-ion batteries. Electrochimica Acta 48:615-621

160. Yuan L, Konstantinov K, Wang GX, Liu HK, Dou SX (2005) Nano-structured SnO2-carbon composites obtained by in situ spray pyrolysis method as anodes in lithium batteries. Journal of Power Sources 146:180-184

161 . Bewlay SL , Konstantinov K , Wang GX , Dou SX , Liu HK (2004) Conductivity improvements to spray-produced LiFePO4 by addition of a carbon source. Materials Letters 58: 1788 - 1791 4

162. Yoshio M, Wang HY, Fukuda K, Umeno T, Dimov N, Ogumi Z (2002) Carbon-coated Si as a lithium-ion battery anode material. Journal of the Electrochemical Society 149:A1598-A1603

163. Kim Y, Goh WH, Chang T, Ha CS, Ree M (2004) Optical and dielectric anisotropy in poly-imide nanocomposite films prepared from soluble poly(amic diethyl ester) precursors. Advanced Engineering Materials 6:39-43

164. Yu J, Ree M, Shin TJ, Park YH, Cai W, Zhou D, Lee KW (2000) Adhesion of poly (4,4'-oxydiphenylene pyromellitimide) to copper metal using a polymeric primer: Effects of miscibility and polyimide precursor origin. Macromolecular Chemistry and Physics 201:491-499

165. Wu YP, Dai XB, Ma JQ, Chen YJ (2004) Lithium Ion Batteries - Practice and Applications. Chemical Industry Press, Beijing

166. Wilson AM, Dahn JR (1995) Lithium Insertion in Carbons Containing Nanodispersed Silicon. Journal of the Electrochemical Society 142:326-332

167. Gratz J, Ahn CC, Yazami R, Fultz B, A194. (1999) Electrochemical Solid-state lett ers 6:A 194

168. Ohara S, Suzuki J, Sekine K, Takamura T (2003) Li insertion/extraction reaction at a Si film evaporated on a Ni foil. Journal of Power Sources 119:591-596

169. Niu J, Lee JY (2002) Electrochemical Solid-State Letters 5:A107

170. Wang CS, Wu GT, Zhang XB, Qi ZF, Li WZ (1998) Lithium insertion in carbon-silicon composite materials produced by mechanical milling. Journal of the Electrochemical Society 145:2751-2758

171 . Menard E , Lee KJ , Khang DY, Nuzzo RG , Rogers JA (2004) A printable form of silicon for high performance thin film transistors on plastic substrates. Applied Physics Letters 84 : 5398 - 5400

172. Chan VZH, Hoffman J, Lee VY, Iatrou H, Avgeropoulos A, Hadjichristidis N, Miller RD, Thomas EL (1999) Ordered bicontinuous nanoporous and nanorelief ceramic films from self assembling polymer precursors. Science 286:1716-1719

173. Maex K, Baklanov MR, Shamiryan D, Iacopi F, Brongersma SH, Yanovitskaya ZS (2003) Low dielectric constant materials for microelectronics. Journal of Applied Physics 93 : 8793 - 8841

174. Morgen M, Ryan ET, Zhao JH, Hu C, Cho TH, Ho PS (2000) Low dielectric constant materials for ULSI interconnects. Annual Review of Materials Science 30:645-680

175. Semiconductor Industry Association (2004) International Technology Roadmap for Semiconductors. Semiconductor Industry Association, San Jose

176 . Ho PKH , Friend RH (2002) pi-electronic and electrical transport properties of conjugated polymer nanocomposites: Poly(p-phenylenevinylene) with homogeneously dispersed silica nanoparticles. Journal of Chemical Physics 116:6782-6794

177. Maier G (2001) Low dielectric constant polymers for microelectronics. Progress in Polymer Science 26:3-65

178. Moylan CR, Best ME, Ree M (1991) Solubility of water in polyimides - quartz crystal microbalance measurements. Journal of Polymer Science Part B-Polymer Physics 29:87-92

179. Carter KR, DiPietro RA, Sanchez MI, Russell TP, Lakshmanan P, McGrath JE (1997) Polyimide nanofoams based on ordered polyimides derived from poly(amic alkyl esters): PMDA/4-BDAF. Chemistry of Materials 9:105-118

Carter KR, DiPietro RA, Sanchez MI, Swanson SA (2001) Nanoporous polyimides derived from highly fluorinated polyimide/poly(propylene oxide) copolymers. Chemistry of Materials 13:213-221

Mikoshiba S, Hayase S (1999) Preparation of low density poly(methylsilsesquioxane)s for LSI interlayer dielectrics with low dielectric constant. Fabrication of angstrom size pores prepared by baking trifluoropropylsilyl copolymers. Journal of Materials Chemistry 9:591-598 Azzam RMA, Bashara NM (1977) Ellipsometry and Polarized Light. North-Holland, Amsterdam

Licata TJ, Colgan EG, Harper JME, Luce SE (1995) Interconnect fabrication processes and the development of low-cost wiring for CMOS products . IBM Journal of Research and Development 39:419-435

Lee YJ, Huang JM, Kuo SW, Chang FC (2005) Low-dielectric, nanoporous polyimide films prepared from PEO-POSS nanoparticles. Polymer 46:10056-10065

Chen GZ, Shaffer MSP, Coleby D, Dixon G, Zhou WZ, Fray DJ, Windle AH (2000) Carbon nanotube and polypyrrole composites: coating and doping. Advanced Materials 12:522-526 Curran SA, Ajayan PM, Blau WJ, Carroll DL, Coleman JN, Dalton AB, Davey AP, Drury A, McCarthy B, Maier S, Strevens A (1998) A composite from poly(m-phenylenevinylene-co-2,5-dioctoxy-p-phenylenevinylene) and carbon nanotubes: A novel material for molecular optoelectronics. Advanced Materials 10:1091-1093

Dai L (1999) Effective bandwidths and performance bounds in high-speed communication systems. Journal of Optimization Theory and Applications 100:549-574 Saito Y, Uemura S, Hamaguchi K (1998) Cathode ray tube lighting elements with carbon nanotube field emitters. Japanese Journal of Applied Physics Part 2-Letters & Express Letters 37 : L346 - L348

Downs C, Nugent J, Ajayan PM, Duquette DJ, Santhanam SV (1999) Efficient polymerization of aniline at carbon nanotube electrodes. Advanced Materials 11:1028-1031 Valter B, Ram MK, Nicolini C (2002) Synthesis of multiwalled carbon nanotubes and poly(o-anisidine) nanocomposite material: Fabrication and characterization of its Langmuir-Schaefer films. Langmuir 18:1535-1541

Zengin H , Zhou WS , Jin JY, Czerw R , Smith DW, Echegoyen L, Carroll DL , Foulger SH , Ballato J (2002) Carbon nanotube doped polyaniline. Advanced Materials 14:1480-1483 Coleman JN , Curran S , Dalton AB , Davey AP, McCarthy B , Blau W, Barklie RC (1998) Percolation-dominated conductivity in a conjugated-polymer-carbon-nanotube composite. Physical Review B 58:R7492-R7495

Lefrant S , Baibarac M , Baltog I , Godon C , Mevellec JY, Wery J , Faulques E , Mihut L , Aarab H, Chauvet O (2005) SERS, FT-IR and photoluminescence studies on single-walled carbon nanotubes/conducting polymers composites . Synthetic Metals 155 : 666 - 669 Woo HS, Czerw R, Webster S, Carroll DL, Park JW, Lee JH (2001) Organic light emitting diodes fabricated with single wall carbon nanotubes dispersed in a hole conducting buffer: the role of carbon nanotubes in a hole conducting polymer. Synthetic Metals 116:369-372 Kymakis E, Amaratunga GAJ (2002) Single-wall carbon nanotube/conjugated polymer photovoltaic devices. Applied Physics Letters 80:112-114

Woo HS, Kim YB, Czerw R, Carroll DL, Ballato J, Ajayan PM (2004) Tailoring hole transport in organic light-emitting devices using carbon nanotube-polymer nanocomposites. Journal of the Korean Physical Society 45:507-511

Star A, Stoddart JF, Steuerman D, Diehl M, Boukai A, Wong EW, Yang X, Chung SW, Choi H, Heath JR (2001) Preparation and properties of polymer-wrapped single-walled carbon nanotubes. Angewandte Chemie-International Edition 40:1721-1725

Qi PF, Javey A, Rolandi M, Wang Q, Yenilmez E, Dai HJ (2004) Miniature organic transistors with carbon nanotubes as quasi-one-dimensional electrodes. Journal of the American Chemical Society 126:11774-11775

Bachtold A, Hadley P, Nakanishi T, Dekker C (2001) Logic circuits with carbon nanotube transistors. Science 294:1317-1320

200. Postma HWC, Teepen T, Yao Z, Grifoni M, Dekker C (2001) Carbon nanotube single-electron transistors at room temperature. Science 293:76-79

201. Yao Z, Dekker C, Avouris P (2001) Carbon Nanotubes. 80:147-171

202. Duan XF, Huang Y, Lieber CM (2002) Nano Letters 2:487-490

203. Ouyang M, Huang JL, Cheung CL, Lieber CM (2001) Science 291:97-100

204 . Rueckes T, Kim K , Joselevich E , Tseng GY, Cheung CL , Lieber CM (2000) Science

205 . Avouris P (2002) Molecular Electronics with Carbon Nanotubes . Accounts of Chemical

Research 35:1026-1034

206 . Liu J , Rinzler AG, Dai HJ , Hafner JH , Bradley RK , Boul PJ, Lu A , Iverson T, Shelimov K ,

Huffman CB, Rodriguez-Macias F, Shon YS, Lee TR, Colbert DT, Smalley RE (1998) Fullerene pipes. Science 280:1253-1256

207. Banerjee S, Wong SS (2002) Functionalization of carbon nanotubes with a metal-containing molecular complex. Nano Letters 2:49-53

208. Banerjee S, Wong SS (2002) Structural characterization, optical properties, and improved solubility of carbon nanotubes functionalized with Wilkinson's catalyst. Journal of the American Chemical Society 124:8940-8948

209. Banerjee S, Wong SS (2002) Synthesis and characterization of carbon nanotube-nanocrystal heterostructures. Nano Letters 2:195-200

210. Dimitrakopoulos CD, Mascaro DJ (2001) Organic thin-film transistors: a review of recent advances. IBM Journal of Research and Development 45:11-27

211. Lodha A, Singh R (2001) Prospects of manufacturing organic semiconductor-based integrated circuits. IEEE Transactions on Semiconductor Manufacturing 14:281-296

212. Martel R, Schmidt T, Shea HR, Hertel T, Avouris P (1998) Single- and multi-wall carbon nanotube field-effect transistors. Applied Physics Letters 73:2447-2449

213. Ramamurthy PC, Malshe AM, Harrell WR, Gregory RV, McGuire K, Rao AM (2004) Polyaniline/single-walled carbon nanotube composite electronic devices. Solid-State Electronics 48:2019-2024

214. Kuo CT, Chiou WH (1997) Field-effect transistor with polyaniline thin film as semiconductor. Synthetic Metals 88 : 23 - 30

215. Javey A, Guo J, Paulsson M, Wang Q, Mann D, Lundstrom M, Dai HJ (2004) High-field quasiballistic transport in short carbon nanotubes. Physical Review Letters 92(10): 106804/1-4

216 . Snow ES , Novak JP, Lay MD , Houser EH , Perkins FK , Campbell PM (2004) Carbon nano-

tube networks: Nanomaterial for macroelectronic applications. Journal of Vacuum Science & Technology B 22:1990-1994

217 . Seidel R , Graham AP, Unger E , Duesberg GS , Liebau M , Steinhoegl W, Kreupl F, Hoenlein W

(2004) High-current nanotube transistors. Nano Letters 4:831-834

218. Seidel RV, Graham AP, Rajasekharan B, Unger E, Liebau M, Duesberg GS, Kreupl F, Hoenlein W (2004) Bias dependence and electrical breakdown of small diameter singlewalled carbon nanotubes . Journal of Applied Physics 96 : 6694 - 6699

219. Tsvetkov MY, Kleshcheva SM, Samoilovich MI, Gaponenko NV, Shushunov AN (2005) Erbium photoluminescence in opal matrix and porous anodic alumina nanocomposites. Microelectronic Engineering 81:273-280

220 . Suzuki N , Tomita Y (2003) Diffraction properties of volume holograms recorded in SiO2 nanoparticle-dispersed methacrylate photopolymer films. Japanese Journal of Applied Physics Part 2-Letters 42 : L927 - L929

221. Siwick BJ, Kalinina O, Kumacheva E, Miller RJD, Noolandi J (2001) Polymeric nanostructured material for high-density three-dimensional optical memory storage. Journal of Applied Physics 90 : 5328 - 5334

222. Parthenopoulous DA, Rentzepis PM (1989) Science 245:843

223. Caruso RA, Antonietti M (2001) Sol-gel nanocoating: an approach to the preparation of structured materials. Chemistry of Materials 13:3272-3282

224. Kawata S, Kawata Y (2000) Three-dimensional optical data storage using photochromic materials. Chemical Reviews 100:1777-1788

225 . Malini KA , Anantharaman MR , Sindhu S , Chinnasamy CN , Ponpandian N , Narayanasamy

A, Balachandran M, Pillai VNS (2001) Effect of cycling on the magnetization of ion exchanged magnetic nanocomposite based on polystyrene. Journal of Materials Science 36:821-824

226 . Suzuki N , Tomita Y (2006) Highly transparent ZrO2 nanoparticle-dispersed acrylate pho topolymers for volume holographic recording. Optics Express 14:12712-12719

227. Kalinina O, Kumacheva E (2001) Nanostructured polymer films with liquid inclusions. 1. Structural blocks. Macromolecules 34:6380-6386

228. Kim E, Park J, Shin C, Kim N (2006) Effect of organic side-chains on the diffraction efficiency of an organic-inorganic hybrid nanocomposite film. Nanotechnology 17:2899-2906

229. Judeinstein P, Oliveira PW, Krug H, Schmidt H (1997) Photochromic organic-inorganic nanocomposites as holographic storage media. Advanced Materials for Optics and Electronics 7:123-133

230 . Trentler TJ , Boyd JE , Colvin VL (2000) Epoxy resin-photopolymer composites for volume holography. Chemistry of Materials 12:1431-1438

231. Suzuki N, Tomita Y (2004) Silica-nanoparticle-dispersed methacrylate photopolymers with net diffraction efficiency near 100%. Applied Optics 43:2125-2129

232. Suzuki N, Tomita Y, Kojima T (2002) Holographic recording in TiO2 nanoparticle-dispersed methacrylate photopolymer films. Applied Physics Letters 81:4121-4123

233 . Tomita Y, Nishibiraki H (2003) Improvement of holographic recording sensitivities in the green in SiO2 nanoparticle-dispersed methacrylate photopolymers doped with pyromethene dyes. Applied Physics Letters 83:410-412

234 . Sanchez C , Escuti MJ , van Heesch C , Bastiaansen CWM , Broer DJ , Loos J , Nussbaumer R

(2005) TiO2 nanoparticle-photopolymer holographic recording . Advanced Functional Materials 15:1623-1629

235. Koshida N, Gelloz B (1999) Wet and dry porous silicon. Current Opinion in Colloid & Interface Science 4:309-313

236. Altukhov PD, Kuzminov EG (1999) Condensation of a hot electron-hole plasma in tunneling silicon MOS structures. Solid State Communications 111:379-384

237. Green MA, Zhao JH, Wang AH, Reece PJ, Gal M (2001) Efficient silicon light-emitting diodes. Nature 412:805-808

238. Pavesi L, Dal Negro L, Mazzoleni C, Franzo G, Priolo F (2000) Optical gain in silicon nanocrystals. Nature 408:440-444

239. Simons AJ, Cox TI, Loni A, Canham LT, Blacker R (1997) Investigation of the mechanisms controlling the stability of a porous silicon electroluminescent device. Thin Solid Films 297:281-284

240. Sticht A, Neufeld E, Luigart A, Brunner K, Abstreiter G, Bay H (1998) Characteristics of surface and waveguide emitting SiGe: Er: O diodes. Journal of Luminescence 80:321-327

241. Amato G, Boarino L, Midellino D, Rossi AM (2000) Philosophical Magazine B 80:679

242. Lu ZH, Grozea D (2002) Crystalline Si/SiO2 quantum wells. Applied Physics Letters 80 : 255 - 257 2

243 . Parisini A , Angelucci R , Dori L , Poggi A , Maccagnani P, Cardinali GC , Amato G , Lerondel

G, Midellino D (2000) TEM characterisation of porous silicon. Micron 31:223-230 244. Lopez HA, Fauchet PM (2001) Infrared LEDs and microcavities based on erbium-doped silicon nanocomposites. Materials Science and Engineering B-Solid State Materials for Advanced Technology 81:91-96

245 . Cristea D , Obreja P, Kusko M , Manea E, Rebigan R (2006) Polymer micromachining for micro- and nanophotonics. Materials Science & Engineering C-Biomimetic and Supramolecular Systems 26:1049-1055

246 . Lal M , Kumar ND , Joshi MP, Prasad PN (1998) Polymerization in a reverse micelle nano-

reactor: Preparation of processable poly(p-phenylenevinylene) with controlled conjugation length. Chemistry of Materials 10:1065-1068

247. Lee J, Cho HJ, Cho NS, Hwang DH, Kang JM, Lim E, Lee JI, Shim HK (2006) Enhanced efficiency of polyfluorene derivatives: Organic-inorganic hybrid polymer light-emitting diodes. Journal of Polymer Science Part A-Polymer Chemistry 44:2943-2954

248. Ho PKH, Kim JS, Tessler N, Friend RH (2001) Photoluminescence of poly(p-phenylenevinylene)-silica nanocomposites: Evidence for dual emission by Franck-Condon analysis. Journal of Chemical Physics 115:2709-2720

249. An HY, Chen BJ, Hou JY, Shen JC, Liu SY (1998) Exciton confinement in organic multiple quantum well structures. Journal of Physics D-Applied Physics 31:1144

250. Yang SH, Nguyen TP, Le Rendu P, Hsu CS (2005) Optical and electrical investigations of poly(p-phenylene vinylene)/silicon oxide and poly(p-phenylene vinylene)/titanium oxide nanocomposites. Thin Solid Films 471:230-235

251. Lee TW, Park OO, Kim JJ, Hong JM, Kim YC (2001) Efficient photoluminescence and electroluminescence from environmentally stable polymer/clay nanocomposites. Chemistry of Materials 13:2217-2222

252. Nguyen T-Q, Wu J, Doan W, Schwartz BJ, Tolbert SH (2000) Science:288

253. Qian L, Zhang T, Wageh S, Jin ZS, Du ZL, Wang YS, Xu XR (2006) Study of blue electroluminescence from titania nanotubes doped into a polymeric matrix. Nanotechnology 17:100-104

254. Lee TW, Park OO, Hong JM, Kim DY, Kim YC (2001) Carrier mobilities of polymer/ organo-clay nanocomposite electroluminescent devices. Thin Solid Films 393:347-351

255. Yokozumi T, Kim SH, Washino K, Lee HC, Ogion K, Usui H, Sato H (2003) Semiconducting nanocomposite from titanium dioxide and organic charge transporting compound. Synthetic Metals 139:151-154

256 . Lee HC , Lee TW, Lim YT, Park OO (2002) Improved environmental stability in poly(p-phenylene vinylene)/layered silicate nanocomposite. Applied Clay Science 21:287-293

257. Lee TW, Park OO, Yoon J, Kim JJ (2001) Enhanced quantum efficiency in polymer/layered silicate nanocomposite light-emitting devices. Synthetic Metals 121:1737-1738

258. Senkevich JJ, Desu SB (1998) Poly(chloro-p-xylylene)/SiO2 multilayer thin films deposited near room temperature by thermal CVD. Thin Solid Films 322:148-157

259 . Senkevich JJ , Desu SB (2000) Compositional studies of near-room-temperature thermal CVD poly(chloro-p-xylylene)/SiO2 nanocomposites. Applied Physics A-Materials Science & Processing 70:541-546

260. Ezhilvalavan S, Tseng TY (1999) Preparation and properties of tantalum pentoxide (Ta2O5) thin films for ultra large scale integrated circuits (ULSIs) application: A review. Journal of Materials Science: Materials in Electronics 10:9-31

261. Chashechnikova I, Dolgov L, Gavrilko T, Puchkovska G, Shaydyuk Y, Lebovka N, Moraru V, Baran J , Ratajczak H (2005) Optical properties of heterogeneous nanosystems based on montmorillonite clay mineral and 5CB nematic liquid crystal. Journal of Molecular Structure 744-747:563-571

262. Zhu W (2001) Vacuum Microelectronics. Wiley, New York

263 . Bajic S , Latham RV (1988) Enhanced cold-cathode emission using composite resin-carbon coatings. Journal of Physics D: Applied Physics 21:200

264. Tsang WM, Stolojan V, Wong SP, Sealy BJ, Silva SRP (2005) The electron field emission properties of ion beam synthesized metal-dielectric nanocomposite layers on silicon substrates. Materials Science and Engineering B-Solid State Materials for Advanced Technology 124:453-457

265 . http://www.nanotechproject.org/ .

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