Repository Universitas Pakuan

Detail Karya Ilmiah Dosen

Agus Ismangil, Irmansyah, Irzaman

Judul : Sifat Optik Lithium Tantalat (Litao3) Diatas Substrat Silikon (100) Tipe-P Bervariasi Suhu

Abstrak : Lithium tantalate, which has chemical formula of LiTaO3,thin filmshave been grownon a p-type Si substrate (100) by using chemical solution deposition and spin coating techniquesat speed of 3000 rpm for 30 seconds. LiTaO3thin films were made inconcentration of 2.5M and at annealing temperatures of 550 Â°C, 600 Â°C, 650 Â°C, 700 Â°C, 750 Â°C, and 800 Â°C. These thin filmswere characterizedby using ocean optic spectroscopy and LCR meter.The results showed thatthe highest absorbance peak of LiTaO3 films was attemperature of 800 Â°C with wavelengths above 800 nm. This indicates that the LiTaO3films was a semiconductor material.

Tahun : 2017 Media Publikasi : Jurnal Nasional Blm Akreditasi

Kategori : Jurnal No/Vol/Tahun : 1 / 14 / 2017

ISSN/ISBN : 16937554

PTN/S : Universitas Pakuan Program Studi : ILMU KOMPUTER

Bibliography :
[1] Marco S, Volkmar N, and Gerald G. 2014. Dielectric and pyroelectric properties of ultrathin, monocrystalline lithium tantalite. Journal infrared Physics & Technology 63:35-41.

[2] Poole C.P. 1998. The Physics Handbook Fundamentals and Key Equations. New York: John Wiley and Son, Inc.

[3] Saito, T, I. 1996. Kimia Anorganik. Permiission of Iwanami Shaten Publisher.

[4] Milan J, Lauhon L, and Allen J. 2005. Photoconductivity of Semiconducting.CdS.

[5] Paula M.V, Nathalie B, Sebastian Z, Pedro F, Maria H.F. 2014. Are lithium niobate (LiNbO3) and lithium tantalate (LiTaO3) ferroelectrics bioactive. Journal Materials Science and Engineering 39:395-402.

[6] Milton O. 1991. The Materials Science of Thin Film. Academic Press Limited, London.

[7] Irzaman, A. Fuad, and M. Barmawi. 2001. Spectral Response of Al/Si Photodiodes for IR Sensor. Proceeding Instrumentation, Measurement, and Communications for the Future, Indonesian German Conference (IGC), Bandung: 340 – 342.

[8] Omar, M.A. 2007. Elementary Solid State Physics. Addison-Wesley Publishing Company.

[9] Song I et al. 2004. Diffusion of Zn in stoichiometric LiTaO3. Journal of Crystal Growth 270: 568–572.

[10] Rio S.R, M.lida.1999. Fisika dan Teknologi Semikonduktor. PT.Pradnya Paramita: Jakarta.

[11] Kwok, K. N. 1995.Complete Guide to Semiconductor Device. McGraw-Hill, inc.

[12] Kuneva M, Christova K and Tonchev S. 2012. Proton-exchanged optical waveguides in LiTaO3: phase composition and stress. Journal of Physics: Conference Series.398.

[13] Liu X. 2005. Nanoscale chemical ething of near-stoichiometric lithium tantalite. Journal Material sains 97(1):30-38.

[14] Sutrisno. 1986. Elektronika Teori dan Penerapannya. Bandung: Institut Teknologi Bandung.

[15] Tipler PA.1991. Physics for Scientist and Engineers. Worth Publisher Inc.

[16] Beata Z, Ewa M, Ryszard J. K. 2012. Synthesis, characterization and photocatalytic properties of lithium tantalite. Journal Materials Characterization 68:71-78.

[17] Chaidir A, Kisworo D. 2007. Pengaruh pemanasan terhadap struktur-mikro, sifat mekanik dan korosi paduan Zr-Nb-Sn-Fe. [Hasil-hasil Penelitian EBN]. ISSN 0854-5561.

[18] Cullity, B.D. 1956. Elements of X-Ray Diffraction. Massachusetts, Addison Wesley Publishing Company.

[19] Irzaman, Maddu A, Syafutra H dan Ismangil A. 2010. Uji konduktivitas listrik dan

dielektrik film tipis lithium tantalate (LiTaO3) yang didadah niobium pentaoksida (Nb2O5) menggunakan metode chemical solution deposition.Prosiding Seminar Nasional Fisika, Bandung: 175-183.

[20] Malvino A V. 1990. Prinsip-prinsip Elektronika. Jakarta: Salemba Teknika.

[21] Uchino K. 2000. Ferroelectric Devices. New York: Marcel Dekker, In

[22] Jun L, Yang L, Zhongxiang Z, Ruyan G, Amar S, and Bhalla. 2013. Structure and dielectric properties of niobium-rich potassium lithium tantalate niobate single crystals. Journal Ceramics International39:8537-8541.

[23] Schwartz, Robert W. 1997. Chemical Solution Deposition of Perovskite Thin Film. Chem. Mater: 2325-2340.

[24] Seo, J.Y, Park S.W. 2004. Chemical Mechanical Planarization Characteristic of Ferroelectric Film for FRAM Applications. International Journal of Korean Physics society 45: 769-772.

[25] Ismangil A, Irmansyah, Irzaman. 2016. The diffusion coefficient of lithium tantalite with temperature variations on LAPAN-IPB satellite infra-red sensor. International Journal of Procedia Environmental Sciences 23: 343 – 444.

[26] Irzaman, Darvina Y, Fuad A, Arifin P, Budiman M dan Barmawi M. 2003. Physical and pyroelectric properties of tantalum oxide doped lead zirconium titanate [Pb0.9950 (Zr0.525 Ti0.465 Ta0.010) O3] thin films and its applications for IR sensor. Physica Status Solidi (a) Germany 199: 416-424.

[27] Irzaman, H. Syafutra, A. Arif, H. Alatas, M. N. Hilaludin, A. Kurniawan, J.Iskandar, M.Dahrul, A. Ismangil, D. Yosman, Aminullah,L. B. Prasetyo, A. Yusuf, and T. M. Kadri. 2014. Formation of solar cells based on Ba0.5 Sr0.5 TiO3 (BST) ferroelectric thick film. Proc. American Institute of Physics (AIP) Conference 1586. 23-34.

[28] Ismangil A, Jenie R P, Irmansyah, Irzaman. 2015. Development of lithium tantalite

(LiTaO3) for automatic switch on LAPAN-IPB Satellite infra-red sensor. International Journal of Procedia Environmental Sciences 24: 329 – 334.

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Detail Karya Ilmiah Dosen

Agus Ismangil, Irmansyah, Irzaman

Judul	:	Sifat Optik Lithium Tantalat (Litao3) Diatas Substrat Silikon (100) Tipe-P Bervariasi Suhu
Abstrak	:	Lithium tantalate, which has chemical formula of LiTaO3,thin filmshave been grownon a p-type Si substrate (100) by using chemical solution deposition and spin coating techniquesat speed of 3000 rpm for 30 seconds. LiTaO3thin films were made inconcentration of 2.5M and at annealing temperatures of 550 Â°C, 600 Â°C, 650 Â°C, 700 Â°C, 750 Â°C, and 800 Â°C. These thin filmswere characterizedby using ocean optic spectroscopy and LCR meter.The results showed thatthe highest absorbance peak of LiTaO3 films was attemperature of 800 Â°C with wavelengths above 800 nm. This indicates that the LiTaO3films was a semiconductor material.
Tahun	:	2017	Media Publikasi	:	Jurnal Nasional Blm Akreditasi
Kategori	:	Jurnal	No/Vol/Tahun	:	1 / 14 / 2017
ISSN/ISBN	:	16937554
PTN/S	:	Universitas Pakuan	Program Studi	:	ILMU KOMPUTER
Bibliography	:	[1] Marco S, Volkmar N, and Gerald G. 2014. Dielectric and pyroelectric properties of ultrathin, monocrystalline lithium tantalite. Journal infrared Physics & Technology 63:35-41. [2] Poole C.P. 1998. The Physics Handbook Fundamentals and Key Equations. New York: John Wiley and Son, Inc. [3] Saito, T, I. 1996. Kimia Anorganik. Permiission of Iwanami Shaten Publisher. [4] Milan J, Lauhon L, and Allen J. 2005. Photoconductivity of Semiconducting.CdS. [5] Paula M.V, Nathalie B, Sebastian Z, Pedro F, Maria H.F. 2014. Are lithium niobate (LiNbO3) and lithium tantalate (LiTaO3) ferroelectrics bioactive. Journal Materials Science and Engineering 39:395-402. [6] Milton O. 1991. The Materials Science of Thin Film. Academic Press Limited, London. [7] Irzaman, A. Fuad, and M. Barmawi. 2001. Spectral Response of Al/Si Photodiodes for IR Sensor. Proceeding Instrumentation, Measurement, and Communications for the Future, Indonesian German Conference (IGC), Bandung: 340 – 342. [8] Omar, M.A. 2007. Elementary Solid State Physics. Addison-Wesley Publishing Company. [9] Song I et al. 2004. Diffusion of Zn in stoichiometric LiTaO3. Journal of Crystal Growth 270: 568–572. [10] Rio S.R, M.lida.1999. Fisika dan Teknologi Semikonduktor. PT.Pradnya Paramita: Jakarta. [11] Kwok, K. N. 1995.Complete Guide to Semiconductor Device. McGraw-Hill, inc. [12] Kuneva M, Christova K and Tonchev S. 2012. Proton-exchanged optical waveguides in LiTaO3: phase composition and stress. Journal of Physics: Conference Series.398. [13] Liu X. 2005. Nanoscale chemical ething of near-stoichiometric lithium tantalite. Journal Material sains 97(1):30-38. [14] Sutrisno. 1986. Elektronika Teori dan Penerapannya. Bandung: Institut Teknologi Bandung. [15] Tipler PA.1991. Physics for Scientist and Engineers. Worth Publisher Inc. [16] Beata Z, Ewa M, Ryszard J. K. 2012. Synthesis, characterization and photocatalytic properties of lithium tantalite. Journal Materials Characterization 68:71-78. [17] Chaidir A, Kisworo D. 2007. Pengaruh pemanasan terhadap struktur-mikro, sifat mekanik dan korosi paduan Zr-Nb-Sn-Fe. [Hasil-hasil Penelitian EBN]. ISSN 0854-5561. [18] Cullity, B.D. 1956. Elements of X-Ray Diffraction. Massachusetts, Addison Wesley Publishing Company. [19] Irzaman, Maddu A, Syafutra H dan Ismangil A. 2010. Uji konduktivitas listrik dan dielektrik film tipis lithium tantalate (LiTaO3) yang didadah niobium pentaoksida (Nb2O5) menggunakan metode chemical solution deposition.Prosiding Seminar Nasional Fisika, Bandung: 175-183. [20] Malvino A V. 1990. Prinsip-prinsip Elektronika. Jakarta: Salemba Teknika. [21] Uchino K. 2000. Ferroelectric Devices. New York: Marcel Dekker, In [22] Jun L, Yang L, Zhongxiang Z, Ruyan G, Amar S, and Bhalla. 2013. Structure and dielectric properties of niobium-rich potassium lithium tantalate niobate single crystals. Journal Ceramics International39:8537-8541. [23] Schwartz, Robert W. 1997. Chemical Solution Deposition of Perovskite Thin Film. Chem. Mater: 2325-2340. [24] Seo, J.Y, Park S.W. 2004. Chemical Mechanical Planarization Characteristic of Ferroelectric Film for FRAM Applications. International Journal of Korean Physics society 45: 769-772. [25] Ismangil A, Irmansyah, Irzaman. 2016. The diffusion coefficient of lithium tantalite with temperature variations on LAPAN-IPB satellite infra-red sensor. International Journal of Procedia Environmental Sciences 23: 343 – 444. [26] Irzaman, Darvina Y, Fuad A, Arifin P, Budiman M dan Barmawi M. 2003. Physical and pyroelectric properties of tantalum oxide doped lead zirconium titanate [Pb0.9950 (Zr0.525 Ti0.465 Ta0.010) O3] thin films and its applications for IR sensor. Physica Status Solidi (a) Germany 199: 416-424. [27] Irzaman, H. Syafutra, A. Arif, H. Alatas, M. N. Hilaludin, A. Kurniawan, J.Iskandar, M.Dahrul, A. Ismangil, D. Yosman, Aminullah,L. B. Prasetyo, A. Yusuf, and T. M. Kadri. 2014. Formation of solar cells based on Ba0.5 Sr0.5 TiO3 (BST) ferroelectric thick film. Proc. American Institute of Physics (AIP) Conference 1586. 23-34. [28] Ismangil A, Jenie R P, Irmansyah, Irzaman. 2015. Development of lithium tantalite (LiTaO3) for automatic switch on LAPAN-IPB Satellite infra-red sensor. International Journal of Procedia Environmental Sciences 24: 329 – 334.
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