Methodology of Accelerated Aging

Joyce, W. B.; Liou, K.‐Y.; Nash, F. R.; Bossard, P. R.; Hartman, R. L.

doi:10.1002/j.1538-7305.1985.tb00446.x

Cited by 48 publications

(22 citation statements)

References 36 publications

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“…Due to the lognormal distribution for degradation behavior of the WGPDs, failure probability of each device as a function of time can be expressed using the average device lifetime and its standard deviation in the following equation [7]:…”

Section: Resultsmentioning

confidence: 99%

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Reliability of InGaAs waveguide photodiodes for 40-Gb/s optical receivers

Joo

Jeon

Lee

et al. 2005

IEEE Trans. Device Mater. Relib.

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The reliability of 1.55-m wavelength InGaAs waveguide photodiodes (WGPDs) fabricated by metal-organic chemical vapor deposition is investigated for 40-Gb/s optical receiver applications. Reliability for both high-temperature storage and accelerated life tests obtained by monitoring both the dark current and the breakdown voltage is examined. The median device lifetime and the activation energy of the degradation mechanism are extracted for WGPD test structures. The device lifetimes are examined via statistical analysis which is highly reliable in predicting the device lifetime under practical conditions. The degradation mechanism for the WGPD test structures can be explained by the formation of leakage current path by ionic impurities in the passivation layer on the exposed p-n junction. Nevertheless, it can be concluded that the WGPD test structures exhibit sufficient reliability for practical 40-Gb/s optical receiver applications.

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Section: Resultsmentioning

confidence: 99%

“…The activation energy for the failure mechanism and the average device lifetime were subsequently computed. It was assumed that the temperature dependence of the device failure rate ( ) obeys the following Arrhenius law [7]:…”

Section: Reliability Testingmentioning

confidence: 99%

Reliability of InGaAs waveguide photodiodes for 40-Gb/s optical receivers

Joo

Jeon

Lee

et al. 2005

IEEE Trans. Device Mater. Relib.

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“…The wear-out degradation occurs for all the material systems such as AlGaAs/GaAs, InGaAsP/InP and AlGaInAs/InP, mainly due to enhanced nonradiative recombination taking place during the aging [15,19,20]. The sudden failure could result from catastrophic optical mirror damage (COMD) [21] or a defect-related failure (such as dark line damage) inside the bulk of the material [22].…”

Section: Device Reliabilitymentioning

confidence: 99%

High-performance AlGaInAs/InP 14xx-nm semiconductor pump lasers for optical amplifications

Qian

Hohl-AbiChedid

et al. 2002

Materials and Devices for Optical and Wireless Communications

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This paper reviews recent progress of high-power 14xx-nm pump lasers using AlGaInAs/InP material. This material has superior temperature characteristics to conventional InGaAsP/InP. As a result, it is more suitable for high current and high efficiency operations as well as uncooled applications for the high power 14xx-nm lasers, which are required for advanced optical amplifications. The laser module consists of a laser chip coupled to a fiber lens and mounted on a thermoelectric cooler in a standard butterfly package. The wavelength of the laser can be stabilized with an external fiber Bragg grating (FBG). We have demonstrated a maximum module fiber output power of 550mW at 1.75A and characteristic temperatures of T 0 = 99K and T 1 = 348K over a range of chip heat-sink temperatures from 15 0 C to 50 0 C. To the best of our knowledge, these are the highest efficiency and temperature characteristics from a single-mode 14xx-nm semiconductor laser module capable of over 0.5W fiber output power. At a chip heat-sink temperature of 70°C, a power of 360mW was obtained for a laser module with FBG, which is the highest reported to date for any wavelengths from 1300nm to 1600nm and would enable uncooled applications of the 14xx-nm lasers in the future.

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“…With some approximation, we discovered that the MCM agrees with the linear extrapolation method for lifetime and activation energy. 6,8,[12][13][14] In the case of a one-component model, if the activation energy of a device is known, one could estimate the lifetime of a device at any temperature from the lifetime measurement performed under stress aging. 8,12,13 From Sim's heuristic model, 3 the lifetime of a device at any operating temperature with the knowledge of the aging behavior at an elevated temperature is given by…”

Section: ͑6͒mentioning

confidence: 99%

Effects of having two populations of defects growing in the cavity of a semiconductor laser

Lam

Mallard²,

Cassidy

2003

Journal of Applied Physics

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Articles you may be interested inMultiwavelength fabrication of vertical-cavity surface-emitting lasers based on asymmetric one-dimensional photonic crystalIn this study, we show the effects of the growth of two noninteracting populations of defects in the cavity of a semiconductor laser diode, induced by accelerated lifetesting. The development of one type of defect is considered to give rise to a particular failure mode or mechanism. Using a multicomponent model, we demonstrate that the evolution of the threshold current as a function of time is strongly affected by the operating temperature. We describe the progression of the degradation in terms of different thermal activation energies associated with each of the different failure modes. This observation explains why a common shape of the aging curve is seldom observed from one experiment to another and why it is difficult to have one universal threshold-aging model that everyone agrees on. In addition, the study offers insight on the estimation of the lifetime of a semiconductor laser diode.

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Methodology of Accelerated Aging

Cited by 48 publications

References 36 publications

Reliability of InGaAs waveguide photodiodes for 40-Gb/s optical receivers

Reliability of InGaAs waveguide photodiodes for 40-Gb/s optical receivers

High-performance AlGaInAs/InP 14xx-nm semiconductor pump lasers for optical amplifications

Effects of having two populations of defects growing in the cavity of a semiconductor laser

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