플라즈마 산화방법을 이용한 질소가 첨가된 실리콘 산화막의 제조와 산화막 내의 질소가 박막트랜지스터의 특성에 미치는 영향

김보현; 이승렬; 안경민; 강승모; 양용호; 안병태; Bo Hyun Kim; Seung Ryul Lee; Kyung Min Ahn; Seung Mo Kang; Yong Ho Yang; Byung Tae Ahn

Korean Journal of Materials Research, Vol.19, No.1, 37-43, January, 2009

DOI10.3740/MRSK.2009.19.1.037 Export Citation

플라즈마 산화방법을 이용한 질소가 첨가된 실리콘 산화막의 제조와 산화막 내의 질소가 박막트랜지스터의 특성에 미치는 영향

Low-Temperature Growth of N-doped SiO2 Layer Using Inductively-Coupled Plasma Oxidation and Its Effect on the Characteristics of Thin Film Transistors

김보현, 이승렬, 안경민, 강승모, 양용호, 안병태^†

한국과학기술원 신소재공학과

Bo Hyun Kim, Seung Ryul Lee, Kyung Min Ahn, Seung Mo Kang, Yong Ho Yang, and Byung Tae Ahn^†

Department of Materials Science and Engineering, KAIST, Daejeon 305-701, Korea

E-mail:

Silicon dioxide as gate dielectrics was grown at 400 oC on a polycrystalline Si substrate by inductively coupled plasma oxidation using a mixture of O2 and N2O to improve the performance of polycrystalline Si thin film transistors. In conventional high-temperature N2O annealing, nitrogen can be supplied to the Si/SiO2 interface because a NO molecule can diffuse through the oxide. However, it was found that nitrogen cannot be supplied to the Si/SiO2 interface by plasma oxidation as the N2O molecule is broken in the plasma and because a dense Si-N bond is formed at the SiO2 surface, preventing further diffusion of nitrogen into the oxide. Nitrogen was added to the Si/SiO2 interface by the plasma oxidation of mixtures of O2/N2O gas, leading to an enhancement of the field effect mobility of polycrystalline Si TFTs due to the reduction in the number of trap densities at the interface and at the Si grain boundaries due to nitrogen passivation.

Keywords:gate oxide;inductively-coupled plasma oxidation;N passivation;thin film transistor

[References]

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Lee JW, Lee NI, Han CH, IEEE Electon Device Lett., 19, 458 (1998)
Carl DA, Hess DW, Lieberman MA, J. Vac. Sci. Technol. A, 8, 2924 (1990)
Chakraborty S, Yoshida T, Hashizume T, Hasegawa H, Saki T, J. Vac. Sci. Technol. B, 16(4), 2159 (1998)
Lee NI, Lee JW, Hur SH, Kim HS, Han CH, IEEE Electron Device Lett., 18, 486 (1997)
Choi YW, Ahn BT, J. Appl. Phys., 86, 4004 (1999)
Choi YW, Park SW, Ahn BT, Appl. Phys. Lett., 74, 2693 (1999)
Ting W, Hwang H, Lee L, Kwong DL, J. Appl. Phys., 70(2), 1072 (1991)
Carr EC, Ellis KA, Buhrman RA, Appl. Phys. Lett., 66, 1492 (1995)
Hedge RI, Tobin PJ, Renid KG, Maiti B, Ajuria SA, J. Appl. Phys., 66, 2882 (1995)
Kim BH, Ahn JH, Ahn BT, Appl. Phys. Lett., 82, 2682 (2003)
Kim BH, Lee SR, Ahn KM, Ahn BT, Electron. Mater. Lett., 4(2), 45 (2008)

[Referenced By]

[1] Lucovsky G, J. Non-Cryst. Solids, 254, 26 (1999)

[2] Lee JW, Lee NI, Han CH, IEEE Electon Device Lett., 19, 458 (1998)

[3] Carl DA, Hess DW, Lieberman MA, J. Vac. Sci. Technol. A, 8, 2924 (1990)

[4] Chakraborty S, Yoshida T, Hashizume T, Hasegawa H, Saki T, J. Vac. Sci. Technol. B, 16(4), 2159 (1998)

[5] Lee NI, Lee JW, Hur SH, Kim HS, Han CH, IEEE Electron Device Lett., 18, 486 (1997)

[6] Choi YW, Ahn BT, J. Appl. Phys., 86, 4004 (1999)

[7] Choi YW, Park SW, Ahn BT, Appl. Phys. Lett., 74, 2693 (1999)

[8] Ting W, Hwang H, Lee L, Kwong DL, J. Appl. Phys., 70(2), 1072 (1991)

[9] Carr EC, Ellis KA, Buhrman RA, Appl. Phys. Lett., 66, 1492 (1995)

[10] Hedge RI, Tobin PJ, Renid KG, Maiti B, Ajuria SA, J. Appl. Phys., 66, 2882 (1995)

[11] Kim BH, Ahn JH, Ahn BT, Appl. Phys. Lett., 82, 2682 (2003)

[12] Kim BH, Lee SR, Ahn KM, Ahn BT, Electron. Mater. Lett., 4(2), 45 (2008)