Title :
Criteria for identifying radiation resistant semiconductor materials
Author :
Messenger, Scott R. ; Burke, Edward A. ; Summers, Geoffrey P. ; Walters, Robert J. ; Warner, Jeffrey H.
Author_Institution :
SFA Inc., Crofton, MD, USA
Abstract :
An index that would reliably rank the relative radiation hardness of semiconductors would be very helpful for selecting materials for many applications. The concept of "concentration of primary defects" (CPD) has been proposed as such an index. Here we show that for the GaAs-InP family of semiconductors used in solar cells, CPD yields results that do not agree with experiment. The long-established concept of damage constants for various semiconductor properties is a more reliable index. For solar cells the relevant damage constant is that for the degradation of minority carrier lifetime. Although the damage constants reported for different semiconductors are specific to a particular type and energy of radiation, we show they can be extended beyond the type and particle energy for which they were originally determined by using nonionizing energy loss (NIEL), thereby greatly extending their possible application.
Keywords :
III-V semiconductors; carrier lifetime; energy loss of particles; gallium arsenide; indium compounds; minority carriers; radiation effects; solar cells; CPD; GaAs; GaAs-InP; InP; NIEL; concentration of primary defects; damage constants; displacement damage; minority carrier lifetime; nonionizing energy loss; particle energy; radiation energy; radiation hardness; radiation resistant semiconductor materials; semiconductor properties; solar cells; Atomic measurements; Charge carrier lifetime; Degradation; Energy loss; Laboratories; Materials reliability; Photovoltaic cells; Radioactive materials; Semiconductor device reliability; Semiconductor materials; Displacement damage; nonionizing energy loss (NIEL);
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2005.860697
