DocumentCode
1054044
Title
Degradation of InGaAsP-InP lasers in hot-humid ambients: determination of temperature-humidity-bias acceleration factors
Author
Osenbach, J.W. ; Comizzol, R.B. ; Evanosky, T.L. ; Chand, Naresh
Author_Institution
AT&T Bell Labs., Breinigsville, PA, USA
Volume
7
Issue
11
fYear
1995
Firstpage
1252
Lastpage
1254
Abstract
Reliable nonhermetic lasers are expected to both reduce the cost of InP-based optoelectronics and lead the way for the development of revolutionary low cost packaging technologies. To date, the functional dependence of the degradation rate of lasers on temperature and humidity in noncondensing ambients is not known, Without knowledge of these dependencies, degradation rates measured in real time, tens to hundreds of hours, at high temperatures, T>60/spl deg/C, and high relative humidities, RH>60%, cannot be used to estimate the degradation rate which occurs at nominal use conditions, T>50/spl deg/C, and RH<50%, Therefore, the field reliability of nonhermetic InP-based lasers is not presently known nor can it be calculated. In this paper, we report the first temperature and humidity acceleration factors for InP-based lasers in nonhermetic, noncondensing ambients. These acceleration factors will, for the first time, provide a tool for estimating the reliability of nonhermetic InP-based lasers in the field.<>
Keywords
III-V semiconductors; environmental testing; gallium arsenide; humidity; indium compounds; laser reliability; semiconductor device packaging; semiconductor lasers; 50 to 60 degC; InGaAsP-InP; InGaAsP-InP laser degradation; InP-based optoelectronics; cost; degradation rate; degradation rates; empirical model; field reliability; functional dependence; high relative humidities; high temperatures; hot-humid ambients; humidity acceleration factors; low cost packaging technologies; nominal use conditions; noncondensing ambients; nonhermetic InP-based lasers; nonhermetic noncondensing ambients; reliable nonhermetic lasers; temperature acceleration factors; temperature-humidity-bias acceleration factors; Acceleration; Corrosion; Costs; Degradation; Fiber lasers; Humidity measurement; Laser modes; Moisture; Packaging; Temperature dependence;
fLanguage
English
Journal_Title
Photonics Technology Letters, IEEE
Publisher
ieee
ISSN
1041-1135
Type
jour
DOI
10.1109/68.473462
Filename
473462
Link To Document