Направленный синтез материалов на основе нанокристаллического SnO2 для повышения селективности газовых сенсоров

Список литературы

1. G. Korotcenkov. Metal oxides for solid-state gas sensors: What determines our choice? //
2. Materials Science and Engineering В 139 (2007) 1−23
3. P. Althainza, A. Dahlke, J. Goschnick, H.J. Ache. Low temperature deposition of glassmembranes for gas sensors // Thin Sol Films 241 (1994) 344−347
4. A. Ryzhikov, M. Labeau, A. Gaskoy. A1203(M = Pt, Ru) catalytic membranes for selectivesemiconductor gas sensors // Sens.Act. В 109 (2005) 91−96
5. X. Huang, L. Wang, Y. Sun, F. Meng, J. Liu. Quantitative analysis of pesticide residue basedon the dynamic response of a single Sn02 gas sensor // Sens. Act. В 99 (2004) 330−335
6. Румянцева M.H., Гаськов A.M. Химическое модифицирование нанокристаллическихоксидов металлов: влияние реальной структуры и химии поверхности на сенсорые свойства // Известия РАН. Серия химическая 57 (2008) 1086−1105.
7. U.-S. Choi, G. Sakai, К. Shimanoe, N. Yamazoe. Sensing properties of Au-loaded
8. Sn02-Co304 composites to CO and H2// Sensors and Actuators В 107 (2005) 397 401
9. A.B. Шапошник. Селективное определение газов полупроводниковыми сенсорами //
10. Диссертация на соискание ученой степени доктора химических наук
11. N. Barsan, D. Koziej, U. Weimar. Metal oxide-based gas sensor research: How to? // Sens.1. Act. В 121 (2007) 18−35
12. M. Rumyantseva, V. Kovalenko, A. Gaskov, E. Makshina, V. Yuschenko, I. Ivanova, A.
13. Ponzoni, G. Faglia, E. Comini. Nanocomposites Sn02/Fe203: Sensor and catalytic properties // Sens. Act. В 118 (2006) 208−214
14. M. Calatayud, A. Markovits, M. Menetrey, B. Mguig, C. Minot. Adsorption on perfect and reduced surfaces of metal oxides // Catal. Today 85 (2003) 125−143
15. A. Gervasini, G. Bellussi, J. Fenyvesi, A. Auroux. Microcalorimetric and Catalytic Studies of the Acidic Character of Modified Metal Oxide Surfaces. 1. Doping Ions on Alumina, Magnesia, and Silica // J. Phys. Chem. 99 (1995) 5117−5125
16. G. Connell, J. A. Dumesic. The Generation of Bronsted and Lewis Acid Sites on the Surface of Silica by Addition of Dopant Cations // Journal of Catalysis 105 (1987) 285−298
17. L. Daza, S. Dassy, B. Delmon. Chemical sensors based on Sn02 and W03 for the detection of formaldehyde: cooperative effects // Sensors and Actuators В Chemical 10 (1993) 99−105
18. G. Busca. The surface acidity of solid oxides and its characterization by IR spectroscopic methods. An attempt at systematization // Physical chemistry chemical physics 1 (1999) 723 736
19. D. Barthomeuf. Conjugate acid-base pairs in zeolites // The Journal of Physical Chemistry 88 (1984) 42−45
20. M. Niwa, Y. Habuta, K. Okumura, N. Katada. Solid acidity of metal oxide monolayer and its role in catalytic reactions // Catalysis Today 87 (2003) 213−218
21. A. Auroux A. Gervasini. Microcalorimetric Study of the Acidity and Basicity of Metal Oxide Surfaces // Journal of Physical Chemistry 94 (1990) 6371−6379
22. H. Idriss, M. Barteau. Active sites on oxides: from single crystals to catalysis // Advances in catalysis 45 (200)261−331
23. J. A. Duffy, M. D. Ingram. Establishment of an optical scale for Lewis basicity in inorganic oxyacids, molten salts, and glasses // Journal of the American Chemical Society 93 (1971) 6448−6454
24. C. K. Jorgensen. Absorption Spectra and Chemical Bonding in Complexes, Pergamon Press, New York, N. Y., 1962, p 138
25. A. L. Tchougreeff, R. Dronskowski. Nephelauxetic effect revisited // International journal of quantum Chemistry 109 (2009) 2606−2621
26. J. A. Duffy. A review of optical basicity and its applications to oxidic systems // Geochimica et Cosmochimica Acta 57 (1993) 3961−3970
27. J. A. Duffy. Chemical bonding in the oxides of elements: a new appraisal // Journal of solid state chemistry 62 (1986) 145−157
28. Jack R. Tessman, A. H. Kahn, W. Shockley. Electronic Polarizabilities of Ions in Crystals // Physical Review 92 (1953) 890−895
29. J. A. Duffy. Ionic-covalent character of Metal and nonmetal oxides // Journal of Physical Chemistry 110 (2006) 13 245−13 248
30. R.G. Pearson. Hard and soft acids and bases // Journal of American Chemical Society 85 (1963)3533−3539
31. Y. Zhang. Electronegativities of elements in Valence States and Their Applications. 1. Electronegativities of elements in valence states // Inorganic Chemistry 21 (1982) 3886−3889
32. Y. Zhang. Electronegativities of elements in valence states and their applications. 2. A scale fro strength of Lewis Acids // Inorganic Chemistiy 21 (1982) 3889−3893
33. J. Portier, G. Campet, J. Etourneau, B. Tanguy. A simple model for the estimation of electronegativities of cations in different electronic states and coordinations / Journal of Alloys and Compounds 209 (1994) 285−289
34. J. Portier, G. Campet, J. Etorneau, M.C.R. Shastry, B. Tanguy. A simple approach to materials design: role played by an ionic-covalent parameter based on polarizing power and electronegativity// Journal of alloys and Compounds 209 (1994) 59−64
35. A. Lebouteller, P. Courtine. Improvement of a bulk optical basicity table for Oxidic Sysytems // Journal of solid state chemistry 137 (1998) 94−103
36. P. Moriceau, A. Lebouteller, E. Bodres, P. Courtine. A new concept related to selectivity in mild oxidation catalysis of hydrocarbons: the optical basicity of catalyst oxygen // Physical Chemistry Chemical Physics 1 (1999) 5735−5744
37. E. Iguchi, H. Nakatsugawa. Application of a polarizable point ion shell model to a two dimensional periodic structure: the NiO (001) surface // Physical Review B 51 (1995)
38. E.A. Mamedov, V.P. Vislovskii, R.M. Talyshinskii, R.G. Rizayev. Role of oxide catalysts basicity in selective oxidation // Studies in Surface Science and Catalysis 72 (1992) 379−386
39. R.T. Sanderson. An Interpretation of Bond Lengths and a Classification of Bonds // Science 114(1951)670−672
40. R.T. Sanderson The interrelationship of bond dissociation energies and contributing bond energies // Journal of the American Chemical Society 97 (1975) 1367−1372
41. N. Ch. Jeong, J. S. Lee, E. L. Tae, Yo.J. Lee, K. B. Yoon. Acidity scale for metal oxides and sanderson’s electronegativities of Lanthanide Elements // Angewandte Chemie 120 (2008) 10 282−10 286
42. A.C.C. Rodrigues. Influence on the electronegativity and on the oxygen charge distribution in a binary hydrolacite-like by modified Sanderson method // Journal of mathematical Chemistry 37 (2005) 347−351
43. M. Huang, A. Adnot, S. Kaliaguine. Cation-Framework Interaction in alkali-cation-exchanged zeolites: an XPS study//journal of the American Chemiacl Society 114 (1992) 10 005−10 010
44. M. Henry. Partial charges distributions in crystalline materials through electronegativity equalization // Materials science forum (152−153) (1994) 355−358
45. P. Nortier, A.P. Borosy, M. Allavena. ab initio Hartree-Fock study of bronsted acidity at the surface of oxides // Journal of Physical Chemistry B 101 (1997) 1347−1354
46. J. Berholic, J.A. Horsley, L. L. Murrel, L.G. Sherman, S. Soled. Bronsted acid sites in transition metal oxide catalysts: modeling of structure, acid strengths and support effects // Journal of Physical Chemistry 91 (1987) 1526−1530
47. A. Shiga, N. Katada, M. Niva. A theoretical study on Bronsted acidity of W03 clusters supported on metal oxide supports by «paired interacting orbitals» (PIO) analysis // Catalysis Today 111 (2006) 333−337
48. G. Busca, E. Finocchio, G. Ramis, G. Ricchiardi. On the role of acidity in catalytic oxidation // Catalysis Today 32 (1996) 133−143
49. P. Mars and D. W. van Krevelen, Special Supplement Chemical Engineering Sciences 3, 41 (1954)
50. E. Finocchio, G. Busca, V. Lorenzelli, R. J. Willey. FTIR Studies on the Selective Oxidation and Combustion of Light Hydrocarbons at Metal Oxide Surfaces // Journal of Chemical Society Faraday Translations 90 (1994) 3347−3356
51. K. Ramesh, L. Chen, F. Chen, Y. Liu, Z. Wang, Y.-F. Han. Re-investigating the CO oxidation mechanism over unsupported MnO, Mn203 and Mn02 catalysts // Catalysis Today 131 (2008) 477−482
52. H. Over, Y. D. Kim, A. P. Seitsonen, S. Wendt, E. Lundgren, M. Schmid, P. Varga, A. Morgante, G. Ertl. Atomic-Scale Structure and Catalytic Reactivity of the Ru02(l 10) Surface // Science 287 (2000) 1474−1476
53. W.-P. HAN, M. AI. The cp-Classification of Metal Oxides for Heterogeneous Oxidation Catalysts // Journal of Catalysis 78 (1982), 281−288
54. A. Bielanski, J. Haber. Oxygen in Catalysis on Transition Metal Oxides // Catalysis Reviews19(1979) 1−41
55. C. R. A. Catlow, R. A. Jackson, J. M. Thoma. Computational Studies of Solid Oxidation Catalystst // Journal of physical chemistry 94 (1990) 7889−7893
56. B.M. Reddy. Redox properties of Metal Oxides // in «Metal Oxides: Chemistry and applications» by J. L. G. Fierro, CRC Press, Taylor & Francis Group Boca Raton 2006, 2115−246
57. Y. Barbaux, A. Elarmani and J.P. Bonelle. Catalytic Oxidation of Methane on Mo03-Si02: Mechanism of oxidation with 02 and N20 studied by surface potential measurements // Catalysis Today, 1 (1987) 147−156
58. G. I. Panov, K. A. Dubkov, E. V. Starokon. Active oxygen in selective oxidation catalysis // Catalysis Today 117 (2006) 148−155
59. H.-F. Liu, R.-S. Liu, K. Y. Liew, R. E. Johnson, and J. H. Lunsford. Partial Oxidation of Methane by Nitrous Oxide over Molybdenum on Silica // Jounal of American Chemical Society 106 (1984) 4117−4121
60. R.K. Grasselli. Fundamental principles of selective heterogeneous oxidation catalysis // Topics in Catalysis 21 (2002) 79−88
61. J. Haber, W. Marczewski, J. Stoch, L. Ungier. Electron spectroscopic studies of the reduction of Mo03 // Berichte der Bunsengesellschaft furphysikalische Chemie 79 (1975) 970−974
62. J. Haber, J. Stoch and L. Ungier. Electron spectroscopic studies of the reduction of WO3 // Journal of Solid State Chemistry 19 (1976) 113−115
63. M. O’Keefe, Fast Ion Transport in Solids, North Holland, Amsterdam, 1973, p. 233.
64. J. M. Thomas. How far is the concept of of isolated active sites valid in solid catalysts? // Topics in Catalysis 50 (2008) 98−105.
65. R. K. Grasselli, D. J. Buttrey, P. DeSanto, Jr., J. D. Burrington, C. G. Lugmair, A. F. Volpe, Jr., T. Weingand. Active centers in Mo-V-Nb-Te-Ox (amm)oxidation catalysts // Catalysis Today 91−92 (2004) 251−258
66. R. K. Grasselli. Selective Oxidation and Ammoxidation of Olefins by Heterogeneous Catalysis // Journal of Chemical Education 63 (1986) 216−221
67. R. K. Grasselli. Selectivity issues in (amm)oxidation catalysis // Catalysis Today 99 (2005) 23−31
68. R. Schlogl. Theory in heterogenous catalysis // Cattech 5 (2001) 146−170
69. A. Bogicevic and D. R. Jennison. Variations in the Nature of Metal Adsorption on Ultrathin AI2O3 Films // Physical Review Letters 82 (1999) 4050−4053
70. X.-G. Wang, A. Chaka, M. Scheffler. Effect of the Environment on a-Al203 (0001) Surface Structures // Physical Review Letters 84 (2000) 3650−3653c
71. J. В. Wagner, О. Timpe, F. A. Hamid, A. Trunschke, U. Wild, D. S. Su, R. K. Widi, S. B. A. Hamid, R. Schlogl. Surface texturing of Mo-V-Te-Nb-Ox selective oxidation catalysts // Topics in Catalysis 38 (2006) 51−58
72. G. J. Hutchings, M. S. Scurrell. Designing oxidation catalysts Are we getting better? // Cattech 7 (2003) 90−10 371
73. Th. Wolkenstein Sur les Differents Types de Liaisons lors de l’Adsorption Chimique sur des Semi-Conducteurs // Advances in Catalysis 9 (1957) 807−817
74. P. B. Weisz. Electronic Barrier Layer Phenomena in Chemisorption and Catalysis // Journal of
75. Chemical Physics 20 (1952) 1483−1484
76. J. Haber, M. Witko. Oxidation catalysis electronic theory revisited // Journal of Catalysis 216 (2003) 416−424
77. K. Klier. The transition state in heterogeneous catalysis // Topics in Catalysis 18 (2002) 141 156
78. B. Grzybowska-Swierkosz. Effect of additives on the physicochemical and catalytic properties of oxide catalysts in selective oxidation reactions // Topics in Catalysis 21 (2002) 35−46
79. M. P. Rosynek. Catalytic Properties of Rare Earth Oxides // Catalysis Reviews Science and Engineering 16 (1977) 111−154
80. G.W. Berkstresser, R.J. Brook, J.M. Whelan // Journal of materials science 9 (1974) 491
81. T. Nakamura, M. Misono Y. Yoneda. Reduction-oxidation and catalytic properties of perovskite-type mixed oxide catalysts (Lai.xSrxCo03) // Chemistry Letters 10 (1981) 15 891 592
82. M.P. van Dijk, J.H.H. ter Maat, G. Roelofs, H. Bosch, G.M.H. van de Velde, P.J. Gellings, A.J. Burggraaf//Materials Research Bulletin 19 (1984) 1149
83. M.J. Verkerk, A.J. Burggraaf // Journal of Electrochemical society 130 (1983) 70
84. S.J. Korf, H.J.A. Koopmans, B.C. Lippens, Jr., A.J. Burggraaf, P.J. Gellings //journal of Chemical Scoiety Faraday Transactions 83 (1987) 1485
85. L. C. Glaeserja, J.F. Brazdil, M.A.Hazle, M. Mehicic, R.K. Grasselli. Identification of Active Oxide Ions in a Bismuth Molybdate Selective Oxidation Catalyst // Journal of Chemical Society Faraday Transactions 81 (1985) 2903−2912
86. Макшина E.B., Жилинская E.A., Абукаис А., Романовский Б. В. Валентное и координационное состояния атомов кобальта в массивных и нанесенных кобальтах лантана // Вестник Московского университета. Серия 2: Химия 48 (2007) 9−11
87. P.J. Gellings and H.J.M. Bouwmeester. Ion and mixed conducting oxides as catalysts // Catalysis Today, 12 (1992) 1−105
88. H. Arai, T. Yamada, K. Eguchi, T. Seiyama. Catalytic combustion of methane over various perovskite-type oxides // Applied Catalysis 26 (1986) 265
89. V.A. Zazhigalov, J. Haber, J. Stoch, I.V. Bacherikova, G.A. komashko, A.I. Pyatnitskaya. n-Butane oxidation on V—P—О catalysts. Influence of alkali and alkaline-earth metal ions as additions // Applied Catalysis A General 134 (1996) 225
90. H. Hakkinen, S. Abbet, A. Sanchez, U. Heiz, U. Landman Structural, Electronic, and Impurity-Doping Effects in Nanoscale Chemistry: Supported Gold Nanoclusters // Angewandte Chemie International Edition 42 (2003) 1297−1300
91. U. Heiz, E. L. Bullock. Fundamental aspects of catalysis on supported metal clusters // Journal of materials Chemistry 14 (2004) 564−577
92. A. Gurlo, N. Barsan, U. Weimar. Gas Sensors Based on Semiconducting Metal Oxides // in «Chemistry and Applications» edited by J. L. G. Fierro, Taylor & Francis 2006
93. N. Barsan, U. Weimar. Conduction Model of Metal Oxide Gas Sensors. // Journal of Electronics 7 (2001) 143−167.
94. H. Ogawa, M. Nishikawa, A. Abe. Hall measurement studies and an electrical conduction model of tin oxide ultrafine particle films. // Journal of Applied Physics 53, n.6 (1982) 4448−4455.
95. В. C. Gates. Supported metal cluster catalysts // Journal of Molecular Catalysis A: Chemical163 (2000) 55−65
96. R. Schlogl, S. Bee Abd Hamid. nanocatalysis: Mature science revisited or something really new? // Angewandte Chemie International Edition 43 (2004) 1628−1637
97. B.B. Ющенко. Расчёт спектров кислотности катализаторов по даннымтермопрограммированной десорбции аммиака. // Журнал физической химии 71, № 4 (1997) 628−632.
98. Бурмистров В.А. Гидратированные оксиды IV и V групп. М.: Наука. 1986. 160 с.
99. M.W. Abee, D.F. Сох. NH3 chemisorption on stoichiometric and oxygen-deficient Sn02 (110) surfaces // Surface Science 520 (2002) 65 77
100. E. Bordes-Richard. Multicomponent Oxides in Selective Oxidation of Alkanes Theoretical Acidity versus Selectivity // Topics in Catalysis 50 (2008) 82−89
101. E. Lopez-Navarrete, A. Caballero, V.M. Orera, F.J. Lazaro, M. Ocana. Oxidation state and localization of chromium ions in Crdoped cassiterite and Cr-doped malayaite // Acta materialia 51 (2003) 2371−2381
102. M. Ivanovskaya, P. Bogdanov, G. Faglia, P. Nelli, G. Sberveglieri, A. Taroni, On the Role of Catalytic Additives in Gas-Sensitivity of Sn02-Mo Based Thin Film Sensors, Sens. Actuators B, 2001, 77, 268.
103. S. C. York, M. W. Abee, D. F. Cox. a-Cr203 (1012): surface characterization and oxygen adsorption // Surface Science 437 (1999) 386−396
104. BF3 Adsorption on r-Cr203 (101h2): Probing the Lewis Basicity of Surface Oxygen Anions // Journal of Physical Chemistry B 105 (2001) 8375−8380
105. F. Boccuzzi, E. Guglieminotti. IR study of Ti02-based gas sensor materials: effect of ruthenium on the oxidation of NH3, (CH3)N, and NO // Sensors and Actuators B 21 (1994) 27−31
106. W.C. Conner, J.L. Falconer. Spillover in Heterogeneous Catalysis. // Chemical Reviews, 95 (1995)759−788.
107. G. Ertl. Reactions at Surfaces: From Atoms to Complexity (Nobel Lecture) // Angewandte Chemie 47 (2008) 3524 3535
108. O. Safonova, I. Bezverkhy, P. Fabrichnyi, M. Rumyantseva, A. Gaskov. Mechanism of CO gas sensitivity of nanocrystalline Sn02 studied by Moessbauer spectroscopy and conductance measurements // Journal of Materials Chemistry 12 (2002) 1174−1178
109. O. Safonova, T. Neisius, A. Ryzhikov, B. Chenevier, A. Gaskov, M. Labeau. Characterisation of the H2 sensing mechanism of Pd-promoted Sn02 by XAS in operando conditions // Chemical Communications 41 (2005) 5202−5204
110. S. Aksel, D. Eder. Catalytic effect of metal oxides on the oxidation resistance in carbon nanotube-inoragnic hybrids // Journal of Materials Chemistry 20 (2010) 9149−9154
111. A. V. Marikutsa, M. N. Rumyantseva, L. V. Yashina, A. M. Gaskov. Role of surface hydroxyl groups in promoting room temperature CO sensing by Pd-modified nanocrystalline Sn02 // Journal of Solid State Chemistry 183 (2010) 2389−2399
112. A.K. Santra, D.W. Goodman. Catalytic oxidation of CO by platinum group metals: from ultrahigh vacuum to elevated pressures // Electrochimica Acta 47 (2002) 3595−3609
113. Janne T. Hirvi, Toni-Jani J. Kinnunen, Mika Suvanto, Tapani A. Pakkanen, Jens K. N0rskov. CO oxidation on PdO surfaces // The Journal of Chemical Physics 133 (2010) 84 704
114. Z. Sljivancanin, B. Hammer. CO oxidation on fully oxygen covered Ru (0001): Role of step edges // Physical review B 81 (2010) 121 413 R
115. A. P. Seitsonen, H. Over Intimate interplay of theory and experiments in model catalysis // Surface Science 603 (2009) 1717−1723
116. S. Harbeck, A. Szatvanyi, N. Barsan, U. Weimar, V. Hoffmann. DRIFT studies of thick film un-doped and Pd-doped Sn02 sensors: temperature changes effect and CO detection mechanism in the presence of water vapour // Thin Solid Films 436 (2003) 76−83
117. S. Wang, Y. Wang, J. Jiang, R. Liu, M. Li, Y. Wang, Y. Su, B. Zhu, S. Zhang, W. Huang, S. Wu. A DRIFTS study of low-temperature CO oxidation over Au/Sn02 catalyst prepared by co-precipitation method // Catalysis Communications 10 (2009) 640−644
118. H. Mortensen L. Diekhoner, A. Baurichter, E. Jensen, A. C. Luntz. Dynamics of ammonia decomposition on Ru (0001) // Journal of Chemical physics 113 (2000) 6882−6887
119. D. A. Hansgen, G. Vlachos, J. G. Chen. Using first principles to predict bimetallic catalysts fort he ammonia decomposition reaction // Nature Chemistry 2 (2010) 484−489
120. M.N. Rumyantseva, O.V. Safonova, M.N. Boulova, L.I. Ryabova, A.M. Gaskov, Dopants in nanocrystalline tin dioxide // Russian Chemical Bulletin, 2003, 52, 1217.
121. T. Pagnier, M. Boulova, A. Galerie, A. Gaskov, G. Lucazeau, Reactivity of Sn02 -CuO nanocrystalline materials with H2S: a coupled electrical and Raman spectroscopic study. // Sensors and Actuators B 71 (2000) 134−139
122. N. Sergent, M. Epifani, E. Comini, G. Faglia, T. Pagnier, Interactions of nanocrystalline tin oxide powder with N02: A Raman spectroscopic study // Sensors and Actuators B Chemical 2007, 126, 1.
123. M.N. Rumyantseva, A.M. Gaskov, N. Rosman, T. Pagnier, J.R. Morante, Raman surface vibration modes in nanocrystalline Sn02 prepared by wet chemical methods: correlations with the gas sensors performances // Chemistry of Materials, 2005, 17, 893.
124. J. Kaur, V.D. Vankar, M.C. Bhatnagar, Effect of M0O3 addition on the N02 sensing properties of Sn02 thin films // Sensors and Actuators B Chemical 2008, 133, 650.
125. M. Ivanovskaya, E. Lutynskaya, P. Bogdanov, The Influence of Molybdenum on the Properties of Sn02 Ceramic Sensors // Sensors and Actuators B Chemical 1998, 48, 387.
126. Z. Zhou, H. Gao, R. Liu, B. Du, Study of structure and property for the N°2+NOi electron transfer system // Journal of Molecular Structure: THEOCHEM, 2001, 545, 179
127. M. Sulka, M. Pitonak, P. Neogrady, M. Urban, Electron affinity of the 02 molecule: CCSD (T) calculations using the optimized virtual orbitals space approach // International Journal of Quantum Chemistry, 2008, 108, 2159
128. P.G. Harrison, E.W. Thornton, Journal of Chemical Society Faraday Transactions 1 72, 2484 (1976)
129. N.V. Pavlenko, A. I. Tripol’skii and G. I. Golodets, Adsorption of acetone and hydrogen on aluminum oxide // Theoretical and Experimental chemistry, 1985, 21,315
130. N. Yamazoe K. Shimanoe. Theory of power laws for semiconductor gas sensors // Sensors and Actuators B: Chemical 128 (2008) 566−573