Geoscience Reference
In-Depth Information
[75] N.A. Toropov, V.P. Barzakovskii, V.V. Lapin, N.N. Kursteva, Composition Diagrams
of Silicate Systems, Nauka, Moscow, 1965.
[76] A.D. Wadsley, Mixed Oxides of Titanium and Niobium. II, Acta Cryst. 14 (1961) 660.
[77] P.B. Jamieson, S.C. Abrahams, Ferroelectric Tungsten Bronze-Type Crystal Structures,
Acta Cryst. B24 (1968) 984.
[78] V.B. Aleksandrov, Experimental Investigations in the Field of Mineralogy and
Geochemistry of Rare Earth Elements, Nauka, Moscow, 19673
11
[79] H. Rebbah, G. DesGardin, B. Raveau, Nonstoichiometric oxides with a layer structure:
The compounds A1-x(Ti1-
3
M1+
3
)O5 J. Solid State Chem. 31 (1980) 321.
[80] S. Andersson, A.D. Wadsley, The crystal structure of Na2Ti3O7, Acta Cryst. 14
(1961) 1245
1249.
[81] S. Anderson, A.D. Wadleg, Crystal Chemistry of Titanates, The crystal structure of
Na2Ti3O7 Acta. Cryst. 14 (1961) 1245
1249.
[82] M. Dion, Y. Piffard,, M. Toumoux, The tetratitanates M2Ti4O9 (M
5
Li, Na, K, Rb,
Cs, Tl, Ag), J. Inorg. Nucl. Chem. 40 (1978) 917
918.
[83] G.S. Gopalakrishna, Synthesis and Characterization of NASICON analogues, The
Hydrothermal growth of Lithium, Ph.D. Thesis, University of Mysore, Mysore, India,
1996, pp. 76
77.
[84] K. Byrappa, B. Sanjeeva Ravi Raj, V. Rajeev, A.B. Kulkarni, R.R. Clemente,
Hydrothermal growth and characterization of Na
2
Ti
3
O
7
, Indian J. Phys. 71A (1997)
131
142.
[85] K. Byrappa, Hydrothermal processing of advanced materials, Kirk
Othmer
Encyclopedia of Chemical Technology, John Wiley, UK, 2005.
[86] M.L. Barsukova, V.A. Kuznetsov, A.N. Lobachev, T.N. Tanakina, Crystallization of
bismuth titanates, Sov. Phys. Crystallogr. 17 (1973) 739
742.
[87] M.L. Barsukova, V.A. Kuznetsov, A.N. Lobachev, Yu.V. Shaldin, Hydrothermal crys-
tallization and some properties of bismuth titanates, J. Cryst. Growth 13/14 (1972)
530
534.
[88] F. Muto, S. Taki, Hydrothermal synthesis of K
2
Li
2
Ti
6
O
14
and its crystal structure,
Bull. Chem. Soc. (1976) 77
82.
[89] M. Sato, T. Utsunomiya, Crystal growth and some properties of R
2
Ti
2
O
7
, Bull. Tokyo
Inst. Technol. 98 (1970) 25
35.
[90] B. Sanjeev Ravi Raj, The Hydrothermal growth of Lithium, Crystal growth, structure
and properties of new superionic conductors, Ph.D. Thesis, University of Mysore,
1996, p. 146.
[91] E.D. Kolb, A.J. Caporaso, R.A. Laudise, The hydrothermal growth of lithium metagal-
late, J. Cryst. Growth 8 (1971) 354
358.
[92] D.J. Marshall, R.A. Laudise, The hydrothermal solubility of lithium metagallate in
NaOH solutions, J. Cryst. Growth 1 (1967) 88
92.
[93] L. Cambi, M. Elli, Processi Idrotermali: Sintesi di Solfuri e Solfosali da Ossidi di
Metalli e di Metalloidi, per Azione del Solfo e dell' Acqua, Nota 1 Chim. e Industr.
(Ital.) 46 (1964) 1275
1279.
[94] L. Cambi, M. Elli, Processi Idrotermali Nota 9 Sintesi di Solfuri e Solfosali di Metalli
Trivalent Chim. e Industr. (Ital.) 48 (1966) 944
951.
[95] L. Cambi, M. Elli, Processi Idrotermali Sintesi di Solfosali Derivati da Solfuro
d'Argentd e Solfuri d'Anti-Monio, Nota 3 Chim. e Industr. (Ital.) 47 (1965) 282
290.
[96] V.A. Kuznetsov, E.P. Efremova, Hydrothermal synthesis of sulphides of divalent
metals, Hydrothermal Synthesis and Growth of Monocrystals, Nauka, Moscow, 1982,
pp. 78
119
