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2017 | OriginalPaper | Buchkapitel

6. Ausgewählte Festkörper mit nanokristallinen Strukturen

verfasst von : Wolfgang R. Fahrner, Reinhart Job

Erschienen in: Nanotechnologie und Nanoprozesse

Verlag: Springer Berlin Heidelberg

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Zusammenfassung

Wir folgen in diesem Abschnitt hauptsächlich der Arbeit von Grabosch [1], in der wesentliche Punkte der Materialdarstellung und seiner Analyse durchgeführt wurden.

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Literatur
1.
Grabosch G (2000) Herstellung und Charakterisierung von PECVD abgeschiedenem mikrokristallinem Silizium. Dissertation am Fachbereich Elektrotechnik. Der Fern Universität, Hagen
2.
Hattori Y, Kruangam D, Katoh K, Nitta Y, Okamoto H, Hamakawa Y (1987) High-conductive wide band gap p-type a-SiC: H prepared by ECR CVD and its application to high efficiency a-Si basis solar cells. In: Proceedings of the 19th IEEE photovoltaic specialists conference, S 689
3.
Konaga M, Takai H, Kim WY, Takahashi K (1985) Preparation of amorphous silicon and related semiconductors by photochemical vapor deposition and their application to solar cells. In: Proceedings of the 19th IEEE photovoltaic specialists conference, S 1372
4.
Kuwanu Y, Tsuda S (1988) High quality p-type a-SiC film doped with B(CH3)3 and its application to a-Si solar cells. Mater Res Soc Symp Proc 118:557CrossRef
5.
Guha S, Ovshinsky SR (1988) P and N-type microcrystalline semiconductor alloy material including band gap widening elements, devices utilizing same. US Patent 4,775,425
6.
Dusane SR (1992) Gap states in hydrogenated microcrystalline silicon by glow discharge technique. J Appl Phys 72:2923CrossRef
7.
Lucovsky G, Wang C, Chen YL (1992) Barrier-limited transport in μc-Si and μc-Si, C thin films prepared by remote plasma-enhanced chemical vapor deposition. J Vac Sci Technol A 10:2025CrossRef
8.
Shimizu I, Hanna H-I, Shirai H (1990) Control of chemical reactions for growth of crystalline Si at low substrate temperature. Mater Res Soc Symp Proc 164:195CrossRef
9.
Komiya T, Kamo A, Kujirai H, Shimizu I, Hanna J-I (1990) Preparation of crystalline Si Thin films by spontaneous chemical deposistion. Mater Res Soc Symp Proc 164:63CrossRef
10.
Tonouchi M, Moriyama F, Miyasato T (1990) Characterization of μc-Si:H films prepared by H2 sputtering. Jap J Appl Phys 29:L385CrossRef
11.
Feng GF, Katiyar M, Yang YH, Abelson JR, Maley N (1992) Growth and structure of microcrystalline silicon by reactive DC magnetron sputtering. Mater Res Soc Symp Proc 258:179CrossRef
12.
Chaudhuri P, Ray S, Barua AK (1984) The effect of mixing hydrogen with silane on the electronic and optical properties of hydrogenated amorphous silicon films. Thin Solid Films 113:261CrossRef
13.
Shirafuji J, Nagata S, Kuwagaki M (1985) Effect of hydrogen dilution of silane on optoelectronic properties in glow discharged hydrogenated silicon films. J Appl Phys 58:3661CrossRef
14.
Meiling H, van den Boogard MJ, Schropp REI, Bezemer J, van der Weg WF (1990) Hydrogen dilution of silane: correlation between the structure and optical band gap in GD a-Si:H Films. Mater Res Soc Symp Proc 192:645CrossRef
15.
Hollingsworth RE, Bhat PK, Madan A (1987) Microcrystalline and wide band gap p+ window layers for a-Si p-i-n solar cells. J Non-Cryst Solids 97&98:309CrossRef
16.
Kroll U, Meier J, Torres P, Pohl J, Shah A (1998) From amorphous to microcrystalline silicon films prepared by hydrogen dilution using VHF (70 MHz) GD technique. J Non-Cryst Solids 227–230:69
17.
Tsai CC, Thompson R, Doland C, Ponce FA, Anderson GB, Wacker B (1988) Transition from amorphous to crystalline silicon: effect of hydrogen on film growth. Mater Res Soc Symp Proc 118:49CrossRef
18.
Schropp REI, Zeman M (1998) Amorphous and microcrystalline silicon solar cells: modelling, materials and devices technology. Kluwer Academic Publishers, BostonCrossRef
19.
20.
Klug HP, Alexander LE (1974) X-Ray diffraction procedures, 2. Aufl. Wiley, New YorkMATH
21.
Borchert D, Hussein R, Fahrner WR (1999) A simple (n) a-Si/(p) c-Si heterojunction cell Process yielding conversion efficiencies up to 15.3 %. In: 11th International photovoltaic science and engineering conference, Sapporo
22.
Kawamoto K, Nakai T, Bab T, Taguchi M, Sakata H, Tsuge S, Uchihashi K, Tanaka M, Kiyama S (2001) A high efficiency HIT solar cell (21,0 % ≈ 100 cm2) with excellent interface properties. In: 12th International photovoltaic science and engineering conference, Jeju
23.
Barrer RM (1978) Zeolites and clay minerals as sorbents and molecular sieves. Academic, London
24.
Derouane EG, Lemos F, Naccache C, Ribeiro FR (1992) Zeolite microporous solids: synthesis, structure, and reactivity. Kluwer Academic Publishers, DordrechtCrossRef
25.
Zhen S, Seff K (2000) Structures of organic sorption complexes of zeolites. Microporous Mesoporous Mater 39:1CrossRef
26.
Caro J, Noack M, Kolsch P, Schafer R (2000) Zeolite membranes – state of their development and perspective. Microporous Mesoporous Mater 38:3CrossRef
27.
Pauling L (1976) Die Natur der chemischen Bindung. Verlag Chemie, Weinheim
28.
Pauling L (1988) General chemistry. Dover Publications, New York
29.
Meier WM, Olson DH, Baerlocher C (1996) Atlas of zeolite structure types. Zeolites 17:1CrossRef
30.
31.
Robson H (Hrsg) (1998) Verified synthesis of zeolite materials. Microporous Mater 22:495
32.
Barrer RM (1981) Hydrothermal chemistry of zeolites. Academic, London
33.
Cheetham AK, Férey G, Loiseau T (1999) Anorganische Materialien mit offenen Gerüsten. Angew Chem 111:3466CrossRef
34.
Charnell JF (1971) Gel growth of large crystals of sodium and sodium X zeolites. J Cryst Growth 8:291CrossRef
35.
Shimizu S, Hamada H (1999) Synthese riesiger Zeolithkristalle durch langsame Auflösung kompakter Ausgangsmaterialien. Angew Chem 111:2891CrossRef
36.
McCusker LB (1998) Product characterization by X-ray powder diffraction (in [151]). Microporous Mater 22:527CrossRef
37.
Jansen K (1998) Characterization of zeolites by scanning electron microscopy (in [151]). Microporous Mater 22:531CrossRef
38.
Stöcker M (1998) Product characterization by nuclear magnetic resonance (in [151]). Microporous Mater 22:533CrossRef
39.
Kuzmany H (1998) Solid-state spectroscopy. Springer, Berlin/Heidelberg/New YorkCrossRef
40.
Ruthven DM (1998) Characterization of zeolites by sorption capacity measurements (in [151]). Microporous Mater 22:537CrossRef
41.
Dyer A (1998) Ion-exchange capacity (in [151]). Microporous Mater 22:543CrossRef
42.
Karge HG (1998) Characterization by infrared spectroscopy (in [151]). Microporous Mater 22:547CrossRef
43.
Flanigen EM, Sands LB (Hrsg) (1998) Advances in chemistry series 101. American Chemical Society, Washington, DC, S 201
44.
Knops-Gerrits PP, De Vos DE, Feijen EJP, Jacobs PA (1997) Raman spectroscopy of zeolites. Microporous Mater 8:3CrossRef
45.
Breck DW (1974) Zeolithe molecular sieves: structure, chemistry and use. Wiley, New York
46.
Schmid G (Hrsg) (1994) Clusters and colloids. Wiley-VCH, Weinheim
47.
Gonsalves KE, Rangarajan WJ (2000) Chemical synthesis of nanostructured metals, metal alloys, and semiconductors. In: Nalwa HS (Hrsg) Handbook of nanostructured materials and nanotechnology. Academic, London
48.
Simon U, Franke ME (2000) Electrical properties of nanoscaled host/guest compounds. Microporous Mesoporous Mater 41:1CrossRef
49.
Exner D, Jäger NI, Kleine A, Schulz-Ekloff G (1988) Reduction-agglomeration model for metal dispersion in platinum-exchanged NaX zeolite. J Chem Faraday Trans 84:4097CrossRef
50.
Ozin GA, Kuperman A, Stein A (1989) Advanced zeolite material science. Angew Chem Intern Ed Engl 28:359CrossRef
51.
Wang Y, Herron N, Mahler W, Suna H (1989) Linear- and nonlinear-optical properties of semiconductor clusters. J Opt Soc Am B6:808CrossRef
52.
Blatter F, Blazey KW (1990) Conduction-electron resonance of Na-Cs alloys in zeolite Y. IBM Research Report, Zürich
53.
Haug K, Srdanov VI, Stucky GD, Metiu H (1992) The absorption spectrum of an electron solvated in sodalite. J Chem Phys 96:3495CrossRef
54.
Ozin GA (1992) Nanochemistry: synthesis in diminishing dimensions. Adv Mater 10:612CrossRef
55.
Ozin GA, Özkar S (1992) Zeolites: a coordination chemistry view of metal-ligand bonding in zeolite guest-host inclusion compounds. Chem Mater 4:551CrossRef
56.
Edwards PP, Woodall LJ, Anderson PA, Armstrong AR, Slaski M (1993) On the possibility of an insulator-metal transition in alkali metal doped zeolites. Chem Soc Rev 22:305CrossRef
57.
Bowes CL, Ozin GA (1998) Tin sulfide clusters in zeolite A, Sn4S6-Y. J Mater Chem 8:1281CrossRef
58.
Herron N (1986) A cobalt oxygen carrier in zeolite Y. A molecular ‚Ship in a Bottle‘. Inorg Chem 25:4714CrossRef
59.
Herron N, Wang Y, Eddy M, Stucky GD, Cox DE, Bein T, Moller K (1989) Structure and optical properties of CdS superclusters in zeolite hosts. J Am Chem Soc 111:530CrossRef
60.
Hirono T, Kawana A, Yamada T (1987) Photoinduced effects in a mordenite-AgI inclusion compound. J Appl Phys 62:1984CrossRef
61.
Nozue Y, Tang ZK, Goto T (1990) Excitions in PbI2 clusters incorporated into zeolite cages. Solid State Commun 73:31CrossRef
62.
Liu X, Thomas JK (1989) Formation and photophysical properties of cds in zeolites with cages and channels. Langmuir 5:58CrossRef
63.
Schwenn HJ, Wark M, Schulz-Ekloff G, Wiggers H, Simon U (1997) Electrical and optical properties of zeolite Y supported SnO2 nanoparticles. Colloid Polym Sci 275:91CrossRef
64.
Wark M, Schwenn HJ, Schulz-Ekloff G, Jäger NI (1992) Structure, photoabsorption and reversibles reactivity of faujasite-supported dispersions of CdO and SnO2. Ber Bunsen Phys Chem 96:1727CrossRef
65.
Brus LE (1986) Electronic wave functions in semiconductor clusters: experiment and theory. J Chem Phys 90:2555CrossRef
66.
Anderson PA, Bell RG, Catlow SRA, Chang FL, Dent AJ, Edwards PP, Gameson I, Hussain I, Porch A, Thomas JM (1996) Matrix-bound nanochemical possibilities. Chem Mater 8:2114CrossRef
67.
Kelly MJ (1995) A model electronic-structure for metal intercalated zeolites. J Phys Condens Matter 7:5507CrossRef
68.
Anderson PA, Edwards PP (1992) A magnetic resonance study of the inclusion compounds of sodium in zeolites: beyond the metal particles. J Am Chem Soc 114:10608CrossRef
69.
Armstrong AR, Anderson PA, Edwards PP (1994) The composition dependence of the structure of potassium-loaded zeolite-A – evolution of a potassium superlatice. J Solid State Chem 111:178CrossRef
70.
Anderson PA, Armstrong AR, Edwards PP (1994) Ionization and delocalization in potassium zeolite-L – a combined neutron-diffraction and electron-spin-resonance study. Angew Chem Intern Ed Engl 33:641CrossRef
71.
Pan M (1996) High resolution electron microscopy in zeolites. Micron 7:219CrossRef
72.
Gallezot P (1979) The state and catalytic properties of platimum and palladium in faujasite-type zeolites. Catal Rev Sci Eng 20:121CrossRef
73.
Homeyer ST, Sachtler WMH (1989) Elementary steps in the formation of highly dispersed palladium in NaY. J Catal 118:266CrossRef
74.
Stein A, Ozin GA (1993) Sodalite Superlattices: from molecules to clusters to expanded insulators, semiconductors and metals. In: von Ballmoos R, Higgins JB, Treacy MMJ (Hrsg) Proceedings from the 9th International zeolite conference, Bd I. Butterworth-Heinemann, S 93
75.
Aparisi A, Fornés V, Márquez F, Moreno R, López C, Meseguer F (1996) Synthesis and optical properties of CdS and Ge clusters in zeolite cages. Solid State Electron 40:641CrossRef
76.
Deson J, Lalo C, Gédéon A, Vasseur F, Fraissard J (1996) Laser-induced luminescence in reduced copper-exchanged Y zeolite. Chem Phys Lett 258:381CrossRef
77.
Chen W, Wang Z, Lin L, Lin J, Su M (1997) Photostimulated luminescence of silver clusters in zeolite-Y. Phys Lett A232:391CrossRef
78.
Chen W, Wang Z, Lin Z, Lin L, Fang K, Xu Y, Su M, Lin J (1998) Photostimulated luminescence of AgI clusters in zeolite-Y. J Appl Phys 83:3811CrossRef
79.
Armand P, Saboungi ML, Price DL, Iton L, Cramer C, Grimsditch M (1997) Nanoclusters in zeolite. Phys Rev Lett 79:2061CrossRef
80.
Mitsa V, Fejsa I (1997) Raman spectra of chalcogenides implanted into pores of zeolites. J Mol Struct 410–411:263
81.
Price GL, Kanazirev V (1997) Guest ordering in zeolite hosts. Zeolites 18:33CrossRef
82.
Caro J, Noack M, Kolsch P, Schafer R (2000) Zeolite membranes – state of their development and perspective. Microporous Mesoporous Mater 38:3CrossRef
83.
Walcarius A (1999) Zeolite-modified electrodes in electrochemical chemistry. Anal Chim Acta 384:1CrossRef
84.
Weitkamp J, Fritz M, Ernst S (1995) Zeolites as media for hydrogen storage. Int J Hydrog Energy 20:967CrossRef
85.
Kynast U, Weiler V (1994) Efficient luminescence from zeolites. Adv Mater 6:937CrossRef
86.
Kelly MJ (1993) The poor prospects for one-dimensional devices. Int J Electron 75:27CrossRef
87.
Videnova-Adrabinska V (1995) The hydrogen bond as a design element in crystal engineering. Two- and three-dimensional building blocks of crystal architecture. J Mol Struct 374:199
88.
Edwards PP, Anderson PA, Woodall LJ, Porch A, Armstrong AR (1996) Can we synthesise a dense bundle of quasi one-dimensional metallic wires? Mater Sci Eng A 217/218:198CrossRef
89.
Anderson PA, Armstrong AR, Edwards PP (1994) Ionisierung und Elektronendelokalisierung in Kalium-Zeolith-L: eine kombinierte Neutronenbeugungs- und ESR-Studie. Angew Chem 106:669CrossRef
90.
Rabo JA, Angell CL, Kasai PH, Schomaker V (1966) Studies of cations in zeolite: adsorption of carbon monoxide; formation of Ni ions and Na3+ 4 centres. Discuss Faraday Soc 41:328
91.
Edwards PP, Harrison MR, Klinowski J, Ramdas S, Thomas JM, Johnson DC, Page CJ. Ionic and metallic clusters in zeolite. J Chem Soc Chem Commun 982
92.
Harrison MR, Edwards PP, Klinowski J, Thomas JM, Johnson DC, Page CJ (1984) Ionic and metallic clusters of the alkali metals in zeolite Y. J Solid State Chem 54:330CrossRef
93.
Anderson PA, Singer RJ, Edwards PP (1991) A new potassium cluster in zeolites X and A. J Chem Soc Chem Commun 914
94.
Anderson PA, Edwards PP (1992) A magnetic resonance study in the inclusion compounds of sodium in zeolites: beyond the metal particle model. J Am Chem Soc 114:10608CrossRef
95.
Armstrong AR, Anderson PA, Woodall LJ, Edwards PP (1994) Structure and electronic properties of cesium-loaded zeolite A. J Phys Chem 98:9279CrossRef
96.
Anderson PA, Edwards PP (1994) Reassessment of the conduction-electron spin resonance of alkali metals in zeolites. Phys Rev B50:7155CrossRef
Metadaten
Titel
Ausgewählte Festkörper mit nanokristallinen Strukturen
verfasst von
Wolfgang R. Fahrner
Reinhart Job
Copyright-Jahr
2017
Verlag
Springer Berlin Heidelberg
Buch
Nanotechnologie und Nanoprozesse

Print ISBN: 978-3-662-48907-9

Electronic ISBN: 978-3-662-48908-6

Copyright-Jahr: 2017

DOI
https://doi.org/10.1007/978-3-662-48908-6_6

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