A Study on Modified Silicon Surface after $CHF_3/C_2F_6$ Reactive Ion Etching

  • Park, Hyung-Ho (Semiconductor Technology Division, Electronics and Telecommunication Research Institute) ;
  • Kwon, Kwang-Ho (Process Development Section, Electronics and Telecommunication Research Institute) ;
  • Lee, Sang-Hwan (Semiconductor Technology Division, Electronics and Telecommunication Research Institute) ;
  • Koak, Byung-Hwa (Semiconductor Technology Division, Electronics and Telecommunication Research Institute) ;
  • Nahm, Sahn (Semiconductor Technology Division, Electronics and Telecommunication Research Institute) ;
  • Lee, Hee-Tae (Semiconductor Technology Division, Electronics and Telecommunication Research Institute) ;
  • Kwon, Oh-Joon (Electronics and Telecommunication Research Institute) ;
  • Cho, Kyoung-Ik (Materials and Characterization Section, Semiconductor Technology Division, ETRI) ;
  • Kang, Young-Il (Electronics and Telecommunication Research Institute (ETRI))
  • Published : 1994.04.30

Abstract

The effects of reactive ion etching (RIE) of $SiO_2$ layer in $CHF_3/C_2F_6$ on the underlying Si surface have been studied by X-ray photoelectron spectroscopy (XPS), secondary ion mass spectrometer, Rutherford backscattering spectroscopy, and high resolution transmission electron microscopy. We found that two distinguishable modified layers are formed by RIE : (i) a uniform residue surface layer of 4 nm thickness composed entirely of carbon, fluorine, oxygen, and hydrogen with 9 different kinds of chemical bonds and (ii) a contaminated silicon layer of about 50 nm thickness with carbon and fluorine atoms without any observable crystalline defects. To search the removal condition of the silicon surface residue, we monitored the changes of surface compositions for the etched silicon after various post treatments as rapid thermal anneal, $O_2$, $NF_3$, $SF_6$, and $Cl_2$ plasma treatments. XPS analysis revealed that $NF_3$ treatment is most effective. With 10 seconds exposure to $NF_3$ plasma, the fluorocarbon residue film decomposes. The remained fluorine completely disappears after the following wet cleaning.

Keywords

References

  1. J. Appl. Phys. v.50 no.8 In situ Auger electron spectroscopy of Si and $SiO_2$ surfaces plasma etched in $CF_4-H_2$ glow discharges Coburn, J.W.
  2. J. Electrochem. Soc. v.137 no.12 An overview of dry etching damage and contamination effects Fonash, S.J.
  3. J. Electrochem. Soc. v.135 no.6 Contamination of silicon surfaces exposed to $CHF_3$ plasmas Cardinaud, C.;Rhounna, A.;Turban, G.;Grolleau, B.
  4. J. Vac. Sci. Technol. A v.8 no.3 Near surface damage and contamination of silicon following electron cyclotron resonance etching Yapsir, A.S.;Fortuno-Wiltshire, G.;Gambino, T.P.;Kastl, R.H.;Parks, C.C.
  5. Japan. J. Appl. Phys. v.29 no.5 A study of $CCl_2F_2$ magnetron ion etching damage and contamination effects in silicon Kuroda, T.;Iwakuro, H.
  6. J. Appl. Phys. v.59 no.8 A study of $CClF_3/H_2$ reactive ion etching damage and contamination effects in silicon Mu, X.C.;Fonash, S.J.;Oehrlein, G.S.;Chakravarti, S.N.;Parks, C.;Keller, J.
  7. Proc. Semicon/Korea Tech. Sympo. An integrated solution for reducing oxide etch-related damage Chu, D.
  8. Proc. 21st Int. Conf. on Solid State Devices and Materials Native oxides formed during wet chemical treatments Takase, K.;Igarashi, T.;Miyata, N.;Moriki, K.;Sugino, R.;Nara, Y.;Ito, T.;Fujisawa, M.;Hattori, T.