Characterization of the piezoresistance in highly doped p-type 3C-SiC at cryogenic temperatures

Hoang-Phuong Phan; Karen M Dowling; Tuan-Khoa Nguyen; Caitlin A Chapin; Toan Dinh; Ruth A Miller; Jisheng Han; Alan Iacopi; Debbie G Senesky; Dzung Viet Dao; Nam-Trung Nguyen

doi:10.1039/c8ra05797d

Characterization of the piezoresistance in highly doped p-type 3C-SiC at cryogenic temperatures

RSC Adv. 2018 Aug 24;8(52):29976-29979. doi: 10.1039/c8ra05797d. eCollection 2018 Aug 20.

Authors

Hoang-Phuong Phan^{1

2}, Karen M Dowling², Tuan-Khoa Nguyen¹, Caitlin A Chapin², Toan Dinh¹, Ruth A Miller², Jisheng Han¹, Alan Iacopi¹, Debbie G Senesky^{2

3}, Dzung Viet Dao^{1

4}, Nam-Trung Nguyen¹

Affiliations

¹ Queensland Micro-Nanotechnology Centre, Griffith University Queensland Australia hoangphuong.phan@griffithuni.edu.au.
² Department of Aeronautics and Astronautic, Stanford University USA.
³ Department of Electrical Engineering, Stanford University CA USA.
⁴ School of Engineering, Griffith University Queensland Australia.

Abstract

This paper reports on the piezoresistive effect in p-type 3C-SiC thin film mechanical sensing at cryogenic conditions. Nanothin 3C-SiC films with a carrier concentration of 2 × 10¹⁹ cm^-3 were epitaxially grown on a Si substrate using the LPCVD process, followed by photolithography and UV laser engraving processes to form SiC-on-Si pressure sensors. The magnitude of the piezoresistive effect was measured by monitoring the change of the SiC conductance subjected to pressurizing/depressurizing cycles at different temperatures. Experimental results showed a relatively stable piezoresistive effect in the highly doped 3C-SiC film with the gauge factor slightly increased by 20% at 150 K with respect to that at room temperature. The data was also in good agreement with theoretical analysis obtained based on the charge transfer phenomenon. This finding demonstrates the potential of 3C-SiC for MEMS sensors used in a large range of temperatures from cryogenic to high temperatures.