The Lattice Compatibility Theory LCT: Physical and Chemical Arguments from the Growth Behavior of Doped Compounds in terms of Bandgap Distortion and Magnetic Effects
Physical and chemical arguments for the recently discussed materials-related Lattice Compatibility Theory are presented. The discussed arguments are based on some differences of Mn ions incorporation kinetics inside some compounds. These differences have been evaluated and quantified in terms of alteration of bandgap edges, magnetic patterns, and Faraday effect. 1. Introduction Bismuth oxides are nanocrystalline, fluorite-type materials which exhibit unexpected lattice expansion during doping stages. They are used in various domains, such as transparent ceramic glass, microelectronics, sensor technology, optical coatings, surface acoustic wave devices, and gas sensing [1–9]. Bismuth ternary oxides, such as Bi12SiO20, Bi4Ge3O12, and Bi4Ti3O12, usually exhibit high oxide ionic conductivity and hence can been used as high-efficiency electrolyte materials for several applications such as oxygen sensors and solid oxide fuel cells (SOFC) [7–10]. Bi4Ge3O12 (BGO, Bismuth germanate) is a high density scintillation inorganic oxide with cubic eulytite structure. It is used in detectors in particle physics, gamma pulse spectroscopy, aerospace physics, and nuclear medicine. Bi4Ti3O12 (BTO, Bismuth titanate) is a layered Aurivillius phase perovskite ferroelectric compound having a Curie temperature of about 675°C. In its monoclinic ferroelectric state, Bi4Ti3O12 has been pointed at as a good candidate for use in nonvolatile memories, thanks to its excellent fatigue resistance during repeated polarization reversals under electrical solicitation. In some recent studies [11, 12], manganese-doped bismuth oxides showed nearly 10 times the ionic conductivity of zirconia despite a low stability in reducing environments. In this study, a support to the Lattice Compatibility Theory LCT is presented in terms of alteration of bandgap edges, magnetic patterns, and Faraday effect. The paper is organized in the following way. In Section 2, some relevant experimental details along with main manganese-doping features are presented. In Section 3, we present physical parameters alteration analysis along with LCT principles. Section 4 is the conclusion. 2. Samples Elaboration and Measurement Techniques Bi4Ti3O12 (BTO), Bi12SiO20 (BSO), and Bi4Ge3O12 (BGO) compounds have been prepared using the polymeric precursor and Czochralski [11–14] methods using titanium tetraisopropoxide, Bismuth acetate, Bi2O3, GeO2 and SiO2 as precursors. Complexation and pH adjustment were achieved using wet ethylene glycol and ammonium hydroxide, respectively. Mn-doping has been achieved using manganese
References
[1]
P. C. Joshi, S. B. Krupanidhi, and A. Mansingh, “Rapid thermally processed ferroelectric Bi4Ti3O12 thin films,” Journal of Applied Physics, vol. 72, no. 11, pp. 5517–5519, 1992.
[2]
S. E. Cummins and L. E. Cross, “Electrical and optical properties of ferroelectric Bi4Ti3O12 single crystals,” Journal of Applied Physics, vol. 39, no. 5, 7 pages, 1968.
[3]
N. F. Mott, Nobel Prize Lecture, 1977.
[4]
W. W. Li, J. J. Zhu, J. D. Wu et al., “Composition and temperature dependence of electronic and optical properties in manganese doped tin dioxide films on quartz substrates prepared by pulsed laser deposition,” ACS Applied Materials and Interfaces, vol. 2, no. 8, pp. 2325–2332, 2010.
[5]
H. Kimura, T. Fukumura, M. Kawasaki, K. Inaba, T. Hasegawa, and H. Koinuma, “Rutile-type oxide-diluted magnetic semiconductor: Mn-doped SnO2,” Applied Physics Letters, vol. 80, no. 1, pp. 94–96, 2002.
[6]
S. J. Liu, C. Y. Liu, J. Y. Juang, and H. W. Fang, “Room-temperature ferromagnetism in Zn and Mn codoped SnO2 films,” Journal of Applied Physics, vol. 105, no. 1, 4 pages, 2009.
[7]
B. Liu, C. W. Cheng, R. Chen, Z. X. Shen, H. J. Fan, and H. D. Sun, “Fine structure of ultraviolet photoluminescence of tin oxide nanowires,” Journal of Physical Chemistry C, vol. 114, no. 8, pp. 3407–3410, 2010.
[8]
G. Sanon, R. Rup, and A. Mansingh, “Band-gap narrowing and band structure in degenerate tin oxide (SnO2) films,” Physical Review B, vol. 44, no. 11, pp. 5672–5680, 1991.
[9]
L. F. Jiang, W. Z. Shen, and Q. X. Guo, “Temperature dependence of the optical properties of AlInN,” Journal of Applied Physics, vol. 106, no. 1, 8 pages, 2009.
[10]
D. Davazoglou, “Determination of optical dispersion and film thickness of semiconducting disordered layers by transmission measurements: application for chemically vapor deposited Si and SnO2 film,” Applied Physics Letters, vol. 70, no. 2, 3 pages, 1997.
[11]
S. P. S. Badwal and K. Foger, “Materials for solid oxide fuel cells,” Materials Forum, vol. 21, pp. 187–224, 1997.
[12]
W. Sch?fer, A. Koch, U. Herold-Schmidt, and D. Stolten, “Materials, interfaces and production techniques for planar solid oxide fuel cells,” Solid State Ionics, vol. 86–88, no. 2, pp. 1235–1239, 1996.
[13]
W. Wardzyński, H. Szymczak, K. Pataj, T. Lukasiewicz, and J. Zmija, “Light induced charge transfer processes in Cr doped Bi12GeO20 and Bi12SiO20 single crystals,” Journal of Physics and Chemistry of Solids, vol. 43, no. 8, pp. 767–769, 1982.
[14]
H. Chen, W. Zhu, E. Kaxiras, and Z. Zhang, “Optimization of Mn doping in group-IV-based dilute magnetic semiconductors by electronic codopants,” Physical Review B, vol. 79, no. 23, 13 pages, 2009.
[15]
M. Bass, Handbook of Optics, vol. 2, McGraw-Hill, 2nd edition, 1995.
[16]
D. A. Van Baak, “Resonant Faraday rotation as a probe of atomic dispersion,” American Journal of Physics, vol. 64, no. 6, p. 724, 1996.
[17]
C. D. Hodgman, Handbook of Chemistry and Physics, vol. 2, Chemical Rubber Publishing, 35th edition, 1953.
[18]
J. H. van der Merwe, “Strain relaxation in epitaxial overlayers,” Journal of Electronic Materials, vol. 20, no. 10, pp. 793–803, 1991.
[19]
M. Ichimura and J. Narayan, “Atomistic study of dislocation nucleation in Ge/(001)Si heterostructuses,” Philosophical Magazine A, vol. 72, no. 2, pp. 281–295, 1995.
[20]
P. Petkova and K. Boubaker, “The Lattice Compatibility Theory (LCT): an attempt to explain Urbach tailing patterns in copper-doped bismuth sillenites (BSO) and germanates (BGO),” Journal of Alloys and Compounds, vol. 546, pp. 176–179, 2013.
[21]
K. Boubaker, “Preludes to the lattice compatibility theory LCT: urbach tailing controversial behavior in some nanocompounds,” ISRN Nanomaterials, vol. 2012, Article ID 173198, 4 pages, 2012.
[22]
K. Boubaker, “The lattice compatibility theory: arguments for recorded I-III-O2 ternary oxide ceramics instability at low temperatures beside ternary telluride and sulphide ceramics,” Journal of Ceramics, vol. 2013, Article ID 734015, 6 pages, 2013.
[23]
K. Boubaker, M. Amlouk, Y. Louartassi, and H. Labiadh, “About unexpected crystallization behaviors of some ternary oxide and sulfide ceramics within lattice compatibility theory LCT framework,” Journal of the Australian Ceramics Society, vol. 49, no. 1, pp. 115–117, 2013.
