The 81st JSAP Autumn Meeting, 2020

Presentation information

Oral presentation

8 Plasma Electronics » 8.6 Plasma Electronics English Session

[11a-Z03-1~4] 8.6 Plasma Electronics English Session

Fri. Sep 11, 2020 8:30 AM - 9:30 AM Z03

Masafumi Jinno(Ehime Univ.)

9:15 AM - 9:30 AM

[11a-Z03-4] Influence of temperature on etch rate of PECVD-SiN films with CF4/H2 plasma

Shihnan Hsiao1, Kazuya Nakane1, Takayoshi Tsutsumi1, Kenji Ishikawa1, Makoto Sekine1, Masaru Hori1 (1.Center for Low-temperature Plasma Sciences, Nagoya University)

Keywords:PECVD SiN film, substrate temperature, bonding structure

The dependences of substrate temperature (from 50 to –20 oC) on etch rate in two series of PECVD SiN films (A and B) with a CF4/H2 mixture plasma were investigated. Thin film characterization including Fourier transformation infrared spectroscopy (FTIR), X-ray reflectivity (XRR), and x-ray photoemission (XPS) of the PECVD SiN films were also conducted to understand the properties of the films. The XRR and XPS indicated that the chemical composition and film density were almost identical. The FTIR shows that the N-H groups were much greater in the A samples than that of B samples. On the contrary, larger fraction in Si-H were found in B samples. The films with greater N-H bonds have a lower etch rate at low temperature (–20 oC) than observed at room temperature and higher; contrarily, the films with a greater Si-H content have a higher etch rate at lower temperature. It was found that the CFx thickness was thicker in the B samples than A samples, suggesting that hydrogen originated from the broken Si-H bond which leads to a polymerization. In addition, a thinner CFx was found in the B samples at low temperature, as a result of higher etch rate. When changing the self-bias voltage, we found that N-H bonding forms easier at low temperature than room temperature. We suggest that the bonding structure of the films and substrate temperature can influence CFx film, fluorine reaction probability and H dissociation in the etching process, which leads to an overall variation of the etch rate.