Understanding dark current in pixels of silicon photomultipliers

Author

Pagano, R. ; Lombardo, S. ; Libertino, S. ; Valvo, G. ; Condorelli, G. ; Carbone, B. ; Sanfilippo, D.N. ; Fallica, G.

Author_Institution

IMM, CNR, Catania, Italy

fYear

2010

fDate

14-16 Sept. 2010

Firstpage

265

Lastpage

268

Abstract

Silicon photomultipliers are nowadays considered a promising alternative to conventional vacuum tube photomultipliers. The physical mechanisms operating in the device need to be fully explored and modeled to understand the device operational limits and possibilities. In this work we study the dark current behavior of the pixels forming the Si photomultiplier as a function of the applied overvoltage and operation temperature. The data are well modeled by assuming that dark current is caused by current pulses triggered by events of diffusion of single minority carriers (mostly electrons) injected from the boundaries of the active area depletion layer (dominating at temperatures above 0°C) and by thermal emission of carriers from Shockley-Read-Hall defects in the depletion layer (dominating at temperatures below 0°C).

Keywords

dark conductivity; overvoltage; photomultipliers; silicon; Shockley-Read-Hall defect; current pulse; dark current behavior; depletion layer; operation temperature; overvoltage; physical mechanism; silicon photomultiplier; thermal emission; vacuum tube photomultiplier; Dark current; Data models; Photomultipliers; Photonics; Pixel; Silicon; Temperature measurement;

fLanguage

English

Publisher

ieee

Conference_Titel

Solid-State Device Research Conference (ESSDERC), 2010 Proceedings of the European

Conference_Location

Sevilla

ISSN

1930-8876

Print_ISBN

978-1-4244-6658-0

Type

conf

DOI

10.1109/ESSDERC.2010.5618368

Filename

5618368