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Piezoelectric field in strained GaAs

Wieczorek, Sebastian; Chow, Weng W.

This report describes an investigation of the piezoelectric field in strained bulk GaAs. The bound charge distribution is calculated and suitable electrode configurations are proposed for (1) uniaxial and (2) biaxial strain. The screening of the piezoelectric field is studied for different impurity concentrations and sample lengths. Electric current due to the piezoelectric field is calculated for the cases of (1) fixed strain and (2) strain varying in time at a constant rate.

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Advances in AlGaN-based deep UV LEDs

Crawford, Mary H.; Allerman, A.A.; Fischer, Arthur J.; Bogart, Katherine B.; Chow, Weng W.; Wieczorek, Sebastian; Kaplar, Robert K.; Kurtz, S.R.

Materials studies of high Al-content (> 30%) AlGaN epilayers and the performance of AlGaN-based LEDs with emission wavelengths shorter than 300 nm are reported. N-type AlGaN films with Al compositions greater than 30% reveal a reduction in conductivity with increasing Al composition. The reduction of threading dislocation density from the 1-5 x10{sup 10} cm{sup -2} range to the 6-9 x 10{sup 9}cm{sup -2} range results in an improvement of electrical conductivity and Al{sub 0.90}Ga{sub 0.10}N films with n= 1.6e17 cm-3 and f{acute Y}=20 cm2/Vs have been achieved. The design, fabrication and packaging of flip-chip bonded deep UV LEDs is described. Large area (1 mm x 1 mm) LED structures with interdigitated contacts demonstrate output powers of 2.25 mW at 297 nm and 1.3 mW at 276 nm when operated under DC current. 300 f{acute Y}m x 300 f{acute Y}m LEDs emitting at 295 nm and operated at 20 mA DC have demonstrated less than 50% drop in output power after more than 2400 hours of operation. Optimization of the electron block layer in 274 nm LED structures has enabled a significant reduction in deep level emission bands, and a peak quantum well to deep level ratio of 700:1 has been achieved for 300 f{acute Y}m x 300 f{acute Y}m LEDs operated at 100 mA DC. Shorter wavelength LED designs are described, and LEDs emitting at 260 nm, 254nm and 237 nm are reported.

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Improved semiconductor-laser dynamics from induced population pulsation

Proposed for publication in Physical Review A.

Wieczorek, Sebastian; Chow, Weng W.

This paper investigates theoretically the modification of dynamical properties in a semiconductor laser by a strong injected signal. It is found that enhanced relaxation oscillations are governed by the pulsations of the intracavity field and population at frequencies determined by the injected field and cavity resonances. Furthermore, the bandwidth enhancement is associated with the undamping of the injection-induced relaxation oscillation and strong population pulsation effects. There are two limitations to the modulation-bandwidth enhancement: Overdamping of relaxation oscillation and degradation of flat response at low frequencies. The injected-laser rate-equations used in the investigation reproduce the relevant aspects of modulation-bandwidth enhancement found in the experiment on injection-locked vertical-cavity surface-emitting lasers.

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Global view of nonlinear dynamics in coupled-cavity lasers : a bifurcation study

Proposed for publication in Optics Communications.

Wieczorek, Sebastian; Chow, Weng W.

This paper investigates nonlinear behavior of coupled lasers. Composite-cavity-mode approach and a class-B description of the active medium are used to describe nonlinearities associated with population dynamics and optical coupling. The multimode equations are studied using bifurcation analysis to identify regions of stable locking, periodic oscillations, and complicated dynamics in the parameter space of coupling-mirror transmission T and normalized cavity-length mismatch dL/{lambda}. We further investigate the evolution of the key bifurcations with the linewidth enhancement factor {alpha}. In particular, our analysis reveals the formation of a gap in the lockband that is gradually occupied by instabilities. We also investigate effects of the cavity-length on chaotic dynamics.

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Bifurcations and interacting modes in coupled lasers: A strong-coupling theory

Physical Review A - Atomic, Molecular, and Optical Physics

Wieczorek, Sebastian; Chow, Weng W.

The synchronization between two coupled lasers was analyzed using a strong-coupling theory. The influences of pump, carrier decay rate, polarization decay rate and coupling mirror losses on synchronization between lasers were investigated using bifurcation analysis, supported by insight provided by analytical solutions. It was found that population pulsation is an essential mode competition mechanism responsible for bistability in the synchronized solutions. The mechanism leading to laser synchronization changes from strong composite-cavity mode competition in class-A regime to frequency locking of composite-cavity modes in class-B regime was discovered.

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7 Results
7 Results