We report recent progress in chemically assisted ion beam etching (CAIBE) of GaN/AlGaN
materials leading to improved performance of 405nm blue lasers fabricated with etched mirrors.
Using a proprietary Etched Facet Technology (EFT) designed for GaN, we have fabricated ridge
lasers in conventional GaN/sapphire material. Typical 3&mgr;m ridge lasers with 600&mgr;m cavity lengths
exhibit threshold currents of 150mA with high yield and cross wafer uniformity. This represents a
factor of five reduction in threshold current over previous results. Additional processing (such as
FIB) was not required to improve the mirror verticality and smoothness as in previous work.
Continuing improvements in laser performance are anticipated with further optimization of facet
smoothness, laser design, and improved epitaxial material. We are also investigating the benefits of
shorter cavity lasers, made feasible by etching, to realize improvements in laser reliability and yield.
The yield advantage is based on the concept that shorter cavity devices will intercept fewer defects
per device. Combined with EFT advantages like low cost wafer-scale testing and monolithic
integration, this is a promising approach for next generation blue lasers for optical storage
applications.
A 1300nm, high power, vertically emitting Fabry Perot laser is presented with a monolithically integrated photodiode. The lasers use ridge waveguide technology with a 45° etched facet to create 30mW of vertically emitted light. Two types of monolithically integrated back facet monitor diodes are discussed togther with their merits for adequate collection efficiency and tracking error. HCSELs with integrated MPDs have passed over 3000 hours of reliability testing.
The Air Force Research Laboratory, Binoptics Corp., and Infotonics Technology Center worked collaboratively to package and characterize recently developed diode based ring lasers that operate at 1550 nm in a diamond shaped cavity. The laser modes propagate bi-directionally; however, uniaxial propagation may be induced by optical injection or by integrating a mirror. Round trip cavity length was 500 μm in 3.5 μm wide ridge waveguides, and four polarization-maintaining lensed fibers provided access to the input and output modes. A signal from a tunable diode laser, incident at one port, served to injection lock both of the counter-propagating circulating modes. When the input signal was time-encoded by an optical modulator, the encoding was transferred to both modes with an inverted time-intensity profile. Performance, in terms of fidelity and extinction ratio, is characterized for selected pulsed and monochromatic formats from low frequencies to those exceeding 12 GHz. A rate equation model is proposed to account for certain aspects of the observed behavior and analog and digital applications are discussed.
In the late 1980's, etched facet lasers were demonstrated at Cornell University using a process based on chemically assisted ion beam etching (CAIBE). These etched facets allowed, for the first time, mirror reflectivities to be obtained that were equal to those of cleaved facets. Over the past few years, BinOptics Corporation has used this proprietary Etched Facet Technology (EFT) in fabricating InP based lasers with a quality equal to those of cleaved facets. Etched facets allow mirrors to be placed on the epitaxial substrate with very high precision. EFT eliminates losses that result from mechanical facet cleaving, allows wafer-scale testing and coating, and enables monolithic integration. BinOptics Corporation has now developed a modified version of its EFT for GaN materials and blue lasers where mechanical cleaving losses can be even more problematic. The relatively high defect density of currently available GaN materials creates an additional yield advantage for EFT: it allows the formation of shorter cavity devices with fewer defects per device. The first etched facet GaN devices are Fabry-Perot type ridge waveguide lasers emitting at 405nm for optical storage applications. However, as demonstrated in InP, it is planned to extend the technology to horizontal-cavity surface-emitting lasers (HCSELs) with integrated monitoring photodetectors (MPDs). A surface-emitting blue laser will allow two-dimensional arrays for high power applications and monolithic integration of additional functions. For example, the integration of a blue HCSEL with a receive detector will enable the creation of a compact optical head.
A horizontal cavity surface-emitting laser (HCSEL) has been demonstrated at 1310nm. The HCSEL incorporates a 45-degree etched facet that produces total internal reflection within the laser cavity. The laser light leaves the cavity at an angle perpendicular to the substrate.
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