MSA  Vol.6 No.2 , February 2015
Preparation of Light-Emitting Ytterbium-Doped Tantalum-Oxide Thin Films Using a Simple Co-Sputtering Method
Abstract: Light-emitting ytterbium-doped tantalum-oxide thin films were prepared using a simple co-sputtering method for the first time. Sharp photoluminescence peaks having a wavelength of around 980 nm were observed from films annealed from 700&degC to 1000&degC for 10 to 40 min. The strongest intensity of the 980-nm peak was obtained from a film deposited using three ytterbium-oxide pellets and annealed at 800&degC for 20 min. Such rare-earth doped tantalum-oxide sputtered films can be used as high-refractive-index materials of autocloned photonic crystals that can be applied to novel light-emitting devices, and they will also be used as both anti-reflection and down-conversion layers for realizing high-efficiency silicon solar cells.
Cite this paper: Miura, K. , Kano, K. , Arai, Y. and Hanaizumi, O. (2015) Preparation of Light-Emitting Ytterbium-Doped Tantalum-Oxide Thin Films Using a Simple Co-Sputtering Method. Materials Sciences and Applications, 6, 209-213. doi: 10.4236/msa.2015.62024.

[1]   Hanaizumi, O., Miura, K., Saito, M., Sato, T., Kawakami, S., Kuramochi, E. and Oku, S. (2000) Frontiers Related with Automatic Shaping of Photonic Crystals. IEICE Transactions on Electronics, E83-C, 912-919.

[2]   Sato, T., Miura, K., Ishino, N., Ohtera, Y., Tamamura, T. and Kawakami, S. (2002) Photonic Crystals for the Visible Range Fabricated by Autocloning Technique and Their Application. Optical and Quantum Electronics, 34, 63-70.

[3]   Miura, K., Ohtera, Y., Ohkubo, H., Akutsu, N. and Kawakami, S. (2003) Reduction of Propagation and Bending Losses of Hetero-Structured Photonic Crystal Waveguides by Use of a High-?Structure. Optics Letters, 28, 734-736.

[4]   Cid, M., Stem, N., Brunetti, C., Beloto, A.F. and Ramos, C.A.S. (1998) Improvements in Anti-Reflection Coatings for High-Efficiency Silicon Solar Cells. Surface and Coatings Technology, 106, 117-120.

[5]   Zhu, M., Zhang, Z. and Miao, W. (2006) Intense Photoluminescence from Amorphous Tantalum Oxide Films. Applied Physics Letters, 89, Article ID: 021915.

[6]   Miura, K., Miyazaki, H. and Hanaizumi, O. (2008) Observation of Blue-Light Emission from Tantalum Oxide Films Deposited by Radio-Frequency Magnetron Sputtering. IEICE Transactions on Electronics, E91-C, 1669-1672.

[7]   Sanada, T., Wakai, Y., Nakashita, H., Matsumoto, T., Yogi, C., Ikeda, S., Wada, N. and Kojima, K. (2010) Preparation of Eu3+-Doped Ta2O5 Phosphor Particles by Sol-Gel Method. Optical Materials, 33, 164-169.

[8]   Singh, M.K., Fusegi, G., Kano, K., Bange, J.P., Miura, K. and Hanaizumi, O. (2009) Intense Photoluminescence from Erbium-Doped Tantalum Oxide Thin Films Deposited by Sputtering. IEICE Electronics Express, 6, 1676-1682.

[9]   Singh, M.K., Miura, K., Fusegi, G., Kano, K. and Hanaizumi, O. (2013) Visible-Light Emission Properties of Erbium- Doped Tantalum-Oxide Films Produced by Co-Sputtering. Key Engineering Materials, 534, 154-157.

[10]   Miura, K., Arai, Y., Osawa, T. and Hanaizumi, O. (2012) Light-Emission Properties of Europium-Doped Tantalum- Oxide Thin Films Deposited by Radio-Frequency Magnetron Sputtering. Journal of Light and Visual Environment, 36, 64-67.

[11]   Miura, K., Osawa, T., Yokota, Y., Suzuki, T. and Hanaizumi, O. (2014) Fabrication of Tm-Doped Ta2O5 Thin Films Using a Co-Sputtering Method. Results in Physics, 4, 148-149.

[12]   Miura, K., Osawa, T., Yokota, Y. and Hanaizumi, O. (2014) Fabrication and Evaluation of Ta2O5:Y2O3 Co-Sputtered Thin Films. Results in Physics, 4, 185-186.

[13]   Ueda, J. and Tanabe, S. (2011) Broadband near Ultra Violet Sensitization of 1 μm Luminescence in Yb3+-Doped CeO2 Crystal. Journal of Applied Physics, 110, Article ID: 073104.

[14]   Rodriguez, V.D., Tikhomirov, V.K., Mendez-Ramos, J., Yanes, A.C. and Moshchalkov, V.V. (2010) Towards Broad Range and Highly Efficient Down-Conversion of Solar Spectrum by Er3+-Yb3+ Co-Doped Nano-Structured Glass-Ce- ramics. Solar Energy Materials and Solar Cells, 94, 1612-1617.