2008
DOI: 10.1364/oe.16.004413
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A distributed feedback silicon evanescent laser

Abstract: We report an electrically pumped distributed feedback silicon evanescent laser. The laser operates continuous wave with a single mode output at 1600 nm. The laser threshold is 25 mA with a maximum output power of 5.4 mW at 10 degrees C. The maximum operating temperature and minimum line width of the laser are 50 degrees C, and 3.6 MHz, respectively.

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Cited by 213 publications
(133 citation statements)
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“…The kinks observed in I ph -I curves at lower stage temperatures and higher output optical power levels are similar to those reported by Fang et al [5] and are attributed to instabilities in the laser optical output caused by the reflections from the corrugations of the adjacent DFB lasers, which are located on the same Si rib waveguide. As the current injection increases, the device heats up and this changes the phase of the reflected light resulting in instabilities in the total optical output.…”
Section: Device Characterizationsupporting
confidence: 86%
See 1 more Smart Citation
“…The kinks observed in I ph -I curves at lower stage temperatures and higher output optical power levels are similar to those reported by Fang et al [5] and are attributed to instabilities in the laser optical output caused by the reflections from the corrugations of the adjacent DFB lasers, which are located on the same Si rib waveguide. As the current injection increases, the device heats up and this changes the phase of the reflected light resulting in instabilities in the total optical output.…”
Section: Device Characterizationsupporting
confidence: 86%
“…Among several types of hybrid III-V/Si lasers, evanescently coupled devices show a great potential for industrial-scale fabrication. Most of the previously demonstrated, evanescently coupled hybrid lasers, including Fabry-Perot [1]- [3], distributed Bragg reflector (DBR) [4], and distributed-feedback (DFB) lasers [5] were based on a molecular (direct) wafer bonding technique which Manuscript received on August 23, 2012. This work was supported by a grant from Intel Corporation and partly supported by the EU-commission through the ERC-grant ULPPIC.…”
Section: Introductionmentioning
confidence: 99%
“…Although silicon is not suited as a light emitter or detector in the infrared, several approaches have been demonstrated to integrate lasers and detectors on a silicon platform [2][3][4][5] modulators and detectors, is an important requirement. This can be achieved by using e.g.…”
Section: Introductionmentioning
confidence: 99%
“…Hydrophilic bonding, adhesion, and hybrid integration techniques for photonic microelectronic fabrication have generated a useful set of active and passive optical components for integration into microelectronic devices [2]. Some of the many photonic structures created include Fabry-Perot cavities [16,19], racetrack rings [20], mode-lock lasers [21], microdisks [22], distributed feedback lasers [23], distributed Bragg reflectors [24], micro-rings [25] lasers, amplifiers [26], PIN [27], metal-semiconductor-metal junctions [28] photodetectors, electroabsorption modulators [29], Mach-Zehnder interferometers [30], micro-disk modulators [31], and high-speed switches [32]. More advanced integration circuits have also been demonstrated [28,33].…”
Section: Integration Of Photonic Components Into Microelectronicsmentioning
confidence: 99%