8
Journal of the American Ceramic Society—Mendoza-Mendoza et al.
21E. G. Gillan and R. B. Kaner, “Synthesis of Refractory Ceramics Via
References
Rapid Metathesis Reactions Between Solid State Precursors,” Chem. Mater.,
8, 333–43 (1996).
1R. W. Simon, C. E. Platt, A. E. Lee, G. S. Lee, K. P. Daly, M. S. Wire, J.
A. Luine, and M. Urbanik, “Low-Loss Substrate for Epitaxial Growth of
High-Temperature Superconductor Thin Film,” Appl. Phys. Lett., 53, 2677–9
(1988).
22G. J. Janz, Molten Salts Handbook. Academic Press Inc, New York, NY,
1967.
23P. Afanasiev and C. Geantet, “Synthesis of Solid Materials in Molten
Nitrates,” Coord. Chem. Rev., 178–180, 1725–52 (1998).
2W. Wu, K. H. Wong, C. L. Choy, and Y. H. Zhang, “Top-Interface-Con-
trolled Fatigue of Epitaxial Pb(Zr0.52Ti0.48)O3 Ferroelectric Thin Films on
La0.7Sr0.3MnO3 Electrodes,” Appl. Phys. Lett., 77, 3441–3 (2000).
3R. Ramesh, A. Inam, W. K. Chan, F. Tillerot, B. Wilkens, C. C. Chang,
T. Sands, J. M. Tarascon, and V. G. Keramidas, “Ferroelectric PbZr0.2Ti0.8O3
Thin Films on Epitaxial Y-Ba-Cu-O,” Appl. Phys. Lett., 59, 3542–4 (1991).
4A. P. Zhuravel, A. V. Ustinov, K. S. Harshavardhan, and S. M. Anlage,
“Influence of LaAlO3 Surface Topography on rf Current Distribution on
Superconducting Microwave Devices,” Appl. Phys. Lett., 81, 4979–81 (2002).
5R. Spinicci, P. Marini, S. D. Rossi, M. Faticanti, and P. Porta, “Oxidative
Coupling of Methane on LaAlO3 Perovskites Partially Substituted with Alkali
or Alkali-Earth Ions,” J. Mol. Catal. A: Chem., 176, 253–65 (2001).
6M. Daturi, G. Busca, and R. J. Willey, “Surface and Structure Character-
ization of Some Perovskite-Type Powders to be used as Combustion Cata-
lysts,” Chem. Mater., 7, 2115–26 (1995).
24C. N. R. Rao, B. Prakash, and M. Natarajan, “Crystal Structure Trans-
formations in Inorganic Nitrites, Nitrates, and Carbonates”; pp. 48, in The
National Standard Reference Data System (NSRDS-NBS 53). National
Bureau of Standards, U.S. Department of Commerce, Washington, 1975.
25A.-E. Gobichon, J.-P. Auffre
´
¨
dic, and D. Louer, “Structure and Thermal
Behaviour of Lanthanum Aluminium Nitrates,” J. Alloy. Compd., 275–277,
130–6 (1998).
26M. D. Shaji Kumar, T. M. Srinivasan, C. Subramanian, and P. Ramasam-
y, “Synthesis of Lanthanum Aluminate by Thermal Decomposition of
Hydrated Nitrates,” Ceram. Int., 23, 419–23 (1997).
27R. Elsebrock, C. Makovicka, P. Meuffels, and R. Waser, “Preparation
and Characterisation of High Density, High Purity Lanthanum Aluminate
Bulk Ceramics,” J. Electroceram., 10, 193–202 (2003).
28A.-E. Gobinchon, J.-P. Auffre
´
¨
dic, and D. Louer, “Thermal Decomposition
7K. Urasaki, Y. Sekine, S. Kawabe, E. Kikuchi, and M. Matsukata, “Cata-
lytic Activities and Coking Resistance of Ni/Perovskites in Steam Reforming
of Methane,” Appl. Cat. A-Gen., 286, 23–9 (2005).
of Neutral and Basic Lanthanum Nitrates Studied with Temperature-Depen-
dent Powder Diffraction and Thermal Analysis,” Solid State Ionics, 93, 51–64
(1997).
29B. Klingenberg and M. A. Vannice, “Influence of Pretreatment on Lantha-
num Nitrate, Carbonate and Oxide Powders,” Chem. Mater., 8, 2755–68
(1996).
8C.-L. Huang and K.-H. Chiang, “Dielectric Properties of B2O3-Doped
(1ꢂx)LaAlO3-XSrTiO3 Ceramic System at Microwave Frequency,” Mater.
Res. Bull., 37, 1941–8 (2002).
30B. Pacewska and M. Keshr, “Thermal Transformations of Aluminium
Nitrate Hydrate,” Thermochim. Acta, 385, 73–80 (2002).
9J. Zylberberg and Z.-G. Ye, “Improved Dielectric Properties in Bismuth-
Doped LaAlO3,” J. Appl. Phys., 100, 086102 (2006).
31M. I. Martı
n, M. E. Rabanal, L. S. Gomez, J. M. Torralba, and O. Milos-
´ ´
10T. L. Nguyen, M. Dokiya, S. Wang, H. Tagawa, and T. Hashimoto, “The
Effect of Oxygen Vacancy on the Oxide Ion Mobility in LaAlO3-Based Oxi-
des,” Solid State Ionics, 130, 229–41 (2000).
evic, “Microstructural and Morphological Analysis of Nanostructured Alu-
mina Particles Synthesized at Low Temperature Via Aerosol Route,” J. Eur.
Ceram. Soc., 28, 2487–94 (2008).
11J. A. Kilner, P. Barrow, and R. J. Brook, “Electrolytes for the High Tem-
perature Fuel Cell; Experimental and Theoretical Studies of the Perovskite
LaAlO3,” J. Power Sources, 3, 67–80 (1978).
32A. Neumann and D. Walter, “The Thermal Transformation from Lantha-
num Hydroxide to Lanthanum Hydroxide Oxide,” Thermochim. Acta, 445,
200–4 (2006).
12T.-Y. Chen and K.-Z. Fung, “Comparison of Dissolution Behavior and
Ionic Conduction Between Sr and/or Mg Doped LaGaO3 and LaAlO3,”
J. Power Sources, 132, 1–10 (2004).
33D. A. Habboush, D. H. Kerridge, and S. A. Tariq, “Molten Nitrate Eu-
tectics: The Reaction of Four Lanthanide Chlorides,” Thermochim. Acta, 65,
53–60 (1983).
13M. Kakihana and T. Okubo, “Low Temperature Powder Synthesis of
LaAlO3 Through In Situ Polymerization Route Utilizing Citric Acid and
Ethylene Glycol,” J. Alloy Compd., 266, 129–33 (1998).
34J. P. Deloume, J.-P. Scharff, P. Marote, B. Durand, and A. Abou-Jalil,
“Molten Alkali Metal Oxonitrates, a Liquid State for Nanosized Perovskite
Phase Elaboration,” J. Mater. Chem., 9, 107–10 (1999).
14S. N. Koc, F. Oksuzomer, E. Yasar, S. Akturk, and M. A. Gurkaynak,
“Effect of Sol-Gel Modifications on Formation and Morphology of Nanocrys-
talline Lanthanum Aluminate,” Mater. Res. Bull., 41, 2291–7 (2006).
15Q. Zhang and F. Saito, “Mechanochemical Synthesis of Lanthanum Alu-
minate by Grinding Lanthanum Oxide with Transition Alumina,” J. Am.
Ceram. Soc., 83, 439–41 (2000).
35D. H. Kerridge and W. M. Shakir, “Molten Lithium Nitrate-Potassium
Nitrate Eutectic: The Reactions of Aluminium, Gallium and Thallium,” Ther-
mochim. Acta, 182, 107–22 (1991).
36Y. Du and D. Inman, “Precipitation of Finely Divided Al2O3 Powders by
a Molten Salt Method,” J. Mater. Chem., 6, 1239–40 (1996).
37C. Matei, D. Berger, P. Marote, S. Stoleriu, and J. P. Deloume, “Lantha-
num-Based Perovskites Obtained in Molten Nitrates or Nitrites,” Prog. Solid
State Chem., 35, 203–9 (2007).
16W. Li, M. W. Zhou, and J. L. Shi, “Synthesizing Nano LaAlO3 Powders
Via Co-Precipitation Method,” Mater. Lett., 58, 365–8 (2004).
17E. Taspinar and A. Cuneyt Tas, “Low-Temperature Chemical Synthesis of
Lanthanum Monoaluminate,” J. Am. Ceram. Soc., 80, 133–41 (1997).
18L. J. Berchmans, S. Angappan, A. Visuvasam, and K. B. R. Kumar,
“Preparation and Characterization of LaAlO3,” Mater. Chem. Phys., 109, 113
–8 (2008).
38J. Yang, R. Li, J. Zhou, X. Li, Y. Zhang, Y. Long, and Y. Li, “Synthesis
of LaMO3 (M = Fe, Co, Ni) Using Nitrate or Nitrite Molten Salts,” J. Alloy
Compd., 508, 301–8 (2010).
39Z. Li, S. Zhang, and W. E. Lee, “Molten Salt Synthesis of LaAlO3 Pow-
ders at low Temperatures,” J. Eur. Ceram. Soc., 27, 3201–5 (2007).
40T. Kojima, K. Nomura, Y. Miyazaki, and K. Tanimoto, “Synthesis of
Various LaMO3 Perovskites in Molten Carbonates,” J. Am. Ceram. Soc., 89,
19Z.-Q. Tian, H.-T. Yu, and Z.-L. Wang, “Combustion Synthesis and Char-
acterization of Nanocrystalline LaAlO3 Powders,” Mater. Chem. Phys., 106,
126–9 (2007).
20M. N. Danchevskaya, Y. D. Ivakin, S. N. Torbin, G. P. Muravieva, and
O. G. Ovchinnikova, “Thermovaporous Synthesis of Complicated Oxides,” J.
Mater. Sci., 41, 1385–90 (2006).
3610–6 (2006).
h