论文信息 - A physical model for boron penetration through an oxynitride gate dielectric prepared by rapid thermal processing in N2O

A physical model for boron penetration through an oxynitride gate dielectric prepared by rapid thermal processing in N2O

In this paper a physical model is presented for boron penetration through an oxynitride gate dielectric prepared by rapid thermal processing in a nitrous oxide (N2O) ambient. Compared with a conventional rapid thermally grown oxide, oxynitride dielectrics show excellent diffusion barrier properties to the dopant (BF2). The Auger electron spectroscopy nitrogen depth profile shows nitrogen pileup at the Si/SiO2 interface, which may explain the lower segregation coefficient (≊20 times lower) of the oxynitride dielectric, as expected from suprem‐iii simulation with modified diffusivity values.

Jack C. Lee | D. Kwong | H. Hwang | W. Ting

[1] Hyunsang Hwang,et al. Electrical characteristics of ultrathin oxynitride gate dielectric prepared by rapid thermal oxidation of Si in N2O , 1990 .

[2] James D. Hayden,et al. The effects of boron penetration on p/sup +/ polysilicon gated PMOS devices , 1990 .

[3] J. Pfiester,et al. A physical model for boron penetration through thin gate oxides from p/sup +/ polysilicon gates , 1990, IEEE Electron Device Letters.

[4] P. S. Davisson,et al. Comparison of the saturated current in normal and inverted modulation-doped In0.53Ga0.47As/InP structures , 1985, IEEE Electron Device Letters.