Journal of the Korean Institute of Electrical and Electronic Material Engineers (한국전기전자재료학회논문지)

The Korean Institute of Electrical and Electronic Material Engineers (한국전기전자재료학회)
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A Study on the Breakdown Voltage Characteristics with Process and Design Parameters in Trench Gate IGBT

트렌치 게이트 IGBT 에서의 공정 및 설계 파라미터에 따른 항복 전압 특성에 관한 연구

  • 신호현 (고려대학교 전기공학과) ;
  • 이한신 (고려대학교 전기공학과) ;
  • 성만영 (고려대학교 전기공학과)
  • Published : 2007.05.01
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Abstract

In this paper, effects of the trench angle($\theta$) on the breakdown voltage according to the process parameters of p-base region and doping concentrations of n-drift region in a Trench Gate IGBT (TIGBT) device were analyzed by computer simulation. Processes parameters used by variables are diffusion temperature, implant dose of p-base region and doping concentration of n-drift region, and aspects of breakdown voltage change with change of each parameter were examined. As diffusion temperature of the p-base region increases, depth of the p-base region increases and effect of the diffusion temperature on the breakdown voltage is very low in the case of small trench angle($45\;^{\circ}$) but that is increases 134.8 % in the case of high trench angle($90\;^{\circ}$). Moreover, as implant dose of the p-base region increases, doping concentration of the p-base region increases and effect of the implant dose on the breakdown voltage is very low in the case of small trench angle($45\;^{\circ}$) but that is increases 232.1 % in the case of high trench angle($90\;^{\circ}$). These phenomenons is why electric field concentrated in the trench is distributed to the p-base region as the diffusion temperature and implant dose of the p-base increase. However, effect of the doping concentration variation in the n-drift region on the breakdown voltage varies just 9.3 % as trench angle increases from $45\;^{\circ}$ to $90\;^{\circ}$. This is why magnitude of electric field concentrated in the trench changes, but direction of that doesn't change. In this paper, respective reasons were analyzed through the electric field concentration analysis by computer simulation.

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References

  1. E. G. Kang and M. Y. Sung, 'A small sized lateral trench electrode IGBT for improving latch-up and breakdown characteristics', Solid-State Electronics, Vol. 46, No.2, p. 295, 2002
  2. E. G. Kang, S. S. Kim, and M. Y. Sung, 'The electrical characteristics of the fabricated lateral trench electrode IGBT for intelligent power K.', International Journal for Manufacturing Science and Production, Vol. 4, No.4, p. 189, 2002
  3. M. Y. Sung, E. G. Kang, D. J. Kim, and S. S. Kim, 'A new lateral trench electrode insulated gate bipolar transistor with p+ diverter for superior electrical characteristics', Japanese Journal of Applied Physics, Vol. 42, No. 4B, p. 2119, 2003 https://doi.org/10.1143/JJAP.42.2119
  4. B. Jayant Baliga, Michael S. Adler, Robert F. Love, Peter V. Gray, and Nathan D. Zomrner, 'The insulated gate transistor: a new threeterminal MOS-controlled bipolar power device', Trans. on Electron Devices, Vol. 31, No. 6, p. 821, 1984
  5. J.-S. Lee, E.-G. Kang, and M.-Y. Sung, 'Improvement of electrical characteristics of vertical NPT trench gate IGBT using trench emitter electrode', J. of KIEEME(in Korean), Vol. 19, No. 10, p. 912, 2006 https://doi.org/10.4313/JKEM.2006.19.10.912
  6. M. Nemoto and B. J. Baliga, 'The recessed-gate IGBT structure', proc. of the ISPSD '99, p. 149, 1999
  7. P. M. Campbell, W. Garwacki, A. R. Sears, P. Mmenditto, and B. J. Baliga, 'Trapezoidalgroove schottky-gate vertical-channel GaAs FET (GaAs static induction transistor)', Electron Device Letters, Vol. 6, No.6, p. 304, 1985 https://doi.org/10.1109/EDL.1985.26133
  8. D. W. Kim, M. Y. Sung, and E. G. Kang, 'A dual trench gate emitter switched thyristor (DTG-EST) with dual trench gate electrode and different gate oxide thickness', Microelectronic Engineering, Vol. 70, No.1, p. 50, 2003 https://doi.org/10.1016/S0167-9317(03)00390-3