Silicon Carbide for High Signal to Noise Ratio MIPs Detection From Room Temperature to 80 $^{\\circ}$ C

Author

Sciortino, S. ; Lagomarsino, S. ; Nava, F.

Volume

56

Issue

4

fYear

2009

Firstpage

2538

Lastpage

2542

Abstract

The relatively low value of the number of electron-hole (e-h) pairs per micron for Minimum Ionizing Particles (MIPs) in SiC against the value for Si, imposes severe constrains on the crystallographic quality, the thickness and the doping concentration of the SiC epitaxial layer used as detection medium. In this work, a 85 mu m thick 4H-SiC epitaxial layer with a low doping concentration, N_eff les 1 times 10¹⁴ cm^-3 , was used in order to have a high number ( ap 4700) of e-h pairs generated by a MIP in the active region. We present experimental data on the charge spectrum for beta MIPs from a ⁹⁰ Sr source, collected in a temperature range from room temperature up to 81degC.

Keywords

crystallography; doping profiles; semiconductor doping; semiconductor epitaxial layers; silicon compounds; solid scintillation detectors; wide band gap semiconductors; SiC; crystallographic quality; doping concentration; electron-hole pair; epitaxial layer; minimum ionizing particle detector; signal-noise ratio; size 85 mum; temperature 20 C to 80 C; Chemical technology; Detectors; Doping; Epitaxial layers; Fabrication; Schottky barriers; Schottky diodes; Signal to noise ratio; Silicon carbide; Temperature distribution; Minimum ionizing particle detectors; Schottky contacts; silicon carbide;

fLanguage

English

Journal_Title

Nuclear Science, IEEE Transactions on

Publisher

ieee

ISSN

0018-9499

Type

jour

DOI

10.1109/TNS.2009.2023848

Filename

5204522

Silicon Carbide for High Signal to Noise Ratio MIPs Detection From Room Temperature to 80 C

Sciortino, S. ; Lagomarsino, S. ; Nava, F.

jour

Silicon Carbide for High Signal to Noise Ratio MIPs Detection From Room Temperature to 80 $^{\\circ}$ C