We report the electrical conduction mechanism of amorphous titanium oxide thin films applied for bolometers. As the O/Ti ratio varies from 1.73 to 1.97 measured by rutherford backscattering spectroscopy, the resistivity of the films increases from 0.26? ?cm to 10.1? ?cm. At the same time, the temperature coefficient of resistivity and activation energy vary from ?1.2% to ?2.3% and from 0.09?eV to 0.18?eV, respectively. The temperature dependence of the electrical conductivity illustrates a thermally activated conduction behavior and the carrier transport mechanism in the titanium oxide thin films is found to obey the normal Meyer-Neldel Rule in the temperature range from 293?K to 373?K. 1. Introduction Titanium dioxide (TiO2) is one of the most widely studied transition metal oxide semiconductors due to its nontoxic nature, chemical stability, and commercial availability at a low cost, robust, and general reactivity. During the past decades, TiO2 thin films have attracted much interest because it has a wide range of promising energy and environmental applications, such as hydrogen generation by water splitting [1], photocatalytic water purification [2], dye-sensitized solar cells [3], and gas sensors [4]. Recently, few people have fabricated amorphous nonstoichiometric titanium dioxide, (a- , where is smaller than 2) thin films by different methods and pointed out that a- thin films are potential thermal sensing material for an uncooled IR bolometer imager [5]. However, the effect of the deposition process on the film structure, composition and electrical properties of this material such as resistivity, temperature coefficient of resistivity (TCR), and activation energy, have not been illustrated up to now, and these factors are very crucial for the detectivity of thermal IR detectors. thin films can be prepared by sol-gel [6], hydrothermal [7], chemical and physical vapor deposition [8]. Reactive sputtering is a commonly used physical vapor deposition method to grow dense and uniform metal oxide films for industrial application [9, 10]. In this process, a metal target is sputtered in an atmosphere consisting of argon and oxygen, this allows higher deposition rates than does the sputtering of an oxide target [10]. It has been experimentally established that the oxygen partial pressure (pO2) during sputtering has the most significant effect on the structure, phase composition, and electrical properties of thin films [11]. TiO2 is electrically insulating with an extremely high resistivity above 108? ?cm, but the suboxidized TiO2 with an excess of titanium
References
[1]
A. Fujishima and K. Honda, “Electrochemical photolysis of water at a semiconductor electrode,” Nature, vol. 238, no. 5358, pp. 37–38, 1972.
[2]
M. R. Hoffmann, S. T. Martin, W. Choi, and D. W. Bahnemann, “Environmental applications of semiconductor photocatalysis,” Chemical Reviews, vol. 95, no. 1, pp. 69–96, 1995.
[3]
B. O'Regan and M. Gr?tzel, “A low-cost, high-efficiency solar cell based on dye-sensitized colloidal TiO2 films,” Nature, vol. 353, no. 6346, pp. 737–740, 1991.
[4]
B. Karunagaran, P. Uthirakumar, S. J. Chung, S. Velumani, and E.-K. Suh, “TiO2 thin film gas sensor for monitoring ammonia,” Materials Characterization, vol. 58, no. 8-9, pp. 680–684, 2007.
[5]
A. L. Lin, “Bolometer having an amorphous titanium oxide layer with high resistance stability,” U.S. Patent 7442933, 2008.
[6]
A. Verma, A. Basu, A. K. Bakhshi, and S. A. Agnihotry, “Structural, optical and electrochemical properties of sol-gel derived TiO2 films: annealing effects,” Solid State Ionics, vol. 176, no. 29-30, pp. 2285–2295, 2005.
[7]
A. Testino, I. R. Bellobono, V. Buscaglia et al., “Optimizing the photocatalytic properties of hydrothermal TiO2 by the control of phase composition and particle morphology. A systematic approach,” Journal of the American Chemical Society, vol. 129, no. 12, pp. 3564–3575, 2007.
[8]
X. Chen and S. S. Mao, “Titanium dioxide nanomaterials: synthesis, properties, modifications and applications,” Chemical Reviews, vol. 107, no. 7, pp. 2891–2959, 2007.
[9]
T. Kubart, O. Kappertz, T. Nyberg, and S. Berg, “Dynamic behaviour of the reactive sputtering process,” Thin Solid Films, vol. 515, no. 2, pp. 421–424, 2006.
[10]
S. Berg and T. Nyberg, “Fundamental understanding and modeling of reactive sputtering processes,” Thin Solid Films, vol. 476, no. 2, pp. 215–230, 2005.
[11]
D. Wicaksana, A. Kobayashi, and A. Kinbara, “Process effects on structural properties of TiO2 thin films by reactive sputtering,” Journal of Vacuum Science and Technology A, vol. 10, pp. 1479–1482, 1992.
[12]
R. G. Breckenridge and W. R. Hosler, “Electrical properties of titanium dioxide semiconductors,” Physical Review, vol. 91, no. 4, pp. 793–802, 1953.
[13]
J. Nowotny, T. Bak, M. K. Nowotny, and L. R. Sheppard, “Titanium dioxide for solar-hydrogen II. Defect chemistry,” International Journal of Hydrogen Energy, vol. 32, no. 14, pp. 2630–2643, 2007.
[14]
P. L?bl, M. Huppertz, and D. Mergel, “Nucleation and growth in TiO2 films prepared by sputtering and evaporation,” Thin Solid Films, vol. 251, no. 1, pp. 72–79, 1994.
[15]
L.-J. Meng, M. Andritschky, and M. P. dos Santos, “The effect of substrate temperature on the properties of d.c. reactive magnetron sputtered titanium oxide films,” Thin Solid Films, vol. 223, no. 2, pp. 242–247, 1993.
[16]
M. Mayer, “SIMNRA, a simulation program for the analysis of NRA, RBS and ERDA,” in AIP Conference Proceedings, vol. 475, pp. 541–544, 1999.
[17]
L.-J. Meng and M. P. dos Santos, “The influence of oxygen partial pressure on the properties of DC reactive magnetron sputtered titanium oxide films,” Applied Surface Science, vol. 68, no. 3, pp. 319–325, 1993.
[18]
D. Mardare, C. Baban, R. Gavrila, M. Modreanu, and G. I. Rusu, “On the structure, morphology and electrical conductivities of titanium oxide thin films,” Surface Science, vol. 507–510, pp. 468–472, 2002.
[19]
K. J. Laidler, “The development of the arrhenius equation,” Journal of Chemical Education, vol. 61, no. 6, pp. 494–498, 1984.
[20]
K. C. Liddiard, “Thin-film resistance bolometer IR detectors,” Infrared Physics, vol. 24, no. 1, pp. 57–64, 1984.
[21]
M. Soltani, M. Chaker, E. Haddad, R. V. Kruzelecky, and J. Margot, “Effects of Ti-W codoping on the optical and electrical switching of vanadium dioxide thin films grown by a reactive pulsed laser deposition,” Applied Physics Letters, vol. 85, no. 11, pp. 1958–1960, 2004.
[22]
M. Vaziri, “Low-temperature conductivity of epitaxial ZnSe in the impurity band regime,” Applied Physics Letters, vol. 65, no. 20, pp. 2568–2570, 1994.
[23]
W. Meyer and H. Neldel, “A relation between the energy constant ε and the quantity constant a in the conductivity-temperature formula for oxide,” Zeitschrift fur Technische Physik, vol. 18, pp. 588–593, 1937.
[24]
R. S. Crandall, “Defect relaxation in amorphous silicon: stretched exponentials, the Meyer-Neldel rule, and the Staebler-Wronski effect,” Physical Review B, vol. 43, no. 5, pp. 4057–4070, 1991.
[25]
N. Mehta, “Meyer-Neldel rule in chalcogenide glasses: recent observations and their consequences,” Current Opinion in Solid State and Materials Science, vol. 14, no. 5, pp. 95–106, 2010.
[26]
K. Shimakawa and F. Abdel-Wahab, “The Meyer-Neldel rule in chalcogenide glasses,” Applied Physics Letters, vol. 70, no. 5, pp. 652–654, 1997.
[27]
J. Fortner, V. G. Karpov, and M.-L. Saboungi, “Meyer-Neldel rule for liquid semiconductors,” Applied Physics Letters, vol. 66, pp. 997–999, 1995.
[28]
G. F. Myachina, T. G. Ermakova, and V. A. Lopyrev, “Compensation effect in the electric conduction in some conjugated polymers,” Physica Status Solidi A, vol. 81, no. 1, pp. 377–380, 1984.
[29]
K. L. Ngai, “Meyer-Neldel rule and anti Meyer-Neldel rule of ionic conductivity conclusions from the coupling model,” Solid State Ionics, vol. 105, no. 1–4, pp. 231–235, 1998.
