Temperature and oxygen concentration effects on anisotropy in chromium hard mask etching for nanoscale fabrication

Chromium and its oxides are valuable as functional materials and plasma-etching hard masks in micro- and nanofabrication. While the continuous decrease in feature sizes opens new opportunities for applications of patterned chromium, the demands placed on the patterning process require a new level of mechanistic understanding. In this work, we investigate plasma etching with chlorine/oxygen chemistry using temperature and oxygen concentration as a means to controllably pattern chromium at the nanometer level. Building on our previous studies on blanket film chromium etching, we look here at patterned trenches 15-100 nm wide in 20 and 10 nm thick chromium films. We vary oxygen concentrations from 1.5% to 81% at substrate temperatures of +20 and -50 degrees C, respectively. Feature and trench profiles are evaluated from high-resolution cross-sectional SEM images. The ternary chromium etch product shows very different profiles as oxygen, temperature, and feature size are varied. We find the highest anisotropy at -50 degrees C and 50% oxygen concentration. Etch results suggest that the redeposition of nonvolatile intermediate reaction compounds enhances anisotropy at low temperature, whereas re-emission of reactive species causes undercut at the higher etching temperature. Published by the AVS.