2016
DOI: 10.1038/nphoton.2016.21
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Electrically pumped continuous-wave III–V quantum dot lasers on silicon

Abstract: Reliable, efficient electrically pumped silicon-based lasers would enable full integration of photonic and electronic circuits, but have previously only been realized by wafer bonding. Here, we demonstrate the first continuous-wave InAs/GaAs quantum-dot lasers directly grown on silicon substrates with a low threshold current density of 62.5 A/cm 2 , a room-temperature output power exceeding 105 mW, lasing operation up to 120 o C, and over 3,100 hours of continuous-wave operating data collected, giving an extra… Show more

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Cited by 753 publications
(518 citation statements)
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“…structures allows the fabrication of lasers in the telecommunication wavelength range with improved performance and lower cost [34]. QDs form as a consequence of the stress generated by the lattice mismatch between the heteroepitaxial layer and the substrate, leading to 3D islanding.…”
Section: Resultsmentioning
confidence: 99%
“…structures allows the fabrication of lasers in the telecommunication wavelength range with improved performance and lower cost [34]. QDs form as a consequence of the stress generated by the lattice mismatch between the heteroepitaxial layer and the substrate, leading to 3D islanding.…”
Section: Resultsmentioning
confidence: 99%
“…epitaxial growth of non-Si materials on Si, enables monolithic integration of devices on the Si platform while taking advantage of the superior optoelectronic properties of non-Si semiconductors. At the telecom band, heteroepitaxial growth has culminated in electrically pumped laser sources on Si based on n-doped Ge [116] and InAs/GaAs quantum dots [117]. In the mid-IR, lasing from heteroepitaxially grown structures on Si has also been achieved based on material systems including GaSb, GeSn, and lead salts.…”
Section: Heteroepitaxy Of Narrow Gap Semiconductors On Simentioning
confidence: 99%
“…10 Recently, direct epitaxy of III-V lasers on Si has attracted significant attention with the successful use of self-assembled quantum dots (QDs) as active materials. [11][12][13] The distinctive zerodimensional density of states of QDs offers lower threshold current density with improved thermal stability in III-V lasers, 14 and their discrete localization promises greater immunity to defects associated with III-V/Si heteroepitaxy when compared to their conventional quantum-well counterparts. 15 More interestingly, these QDs are capable of bending or pinning the threading dislocations (TDs) because of their large strain field.…”
mentioning
confidence: 99%
“…15 More interestingly, these QDs are capable of bending or pinning the threading dislocations (TDs) because of their large strain field. 16,17 Recently, high performance electrically pumped continuous-wave InAs/GaAs QD lasers with an emission wavelength as long as 1315 nm have been directly grown on offcut silicon substrates, 11 yielding a low threshold current density of 62.5 A cm À2 , and an elevated operation temperature up to 120 C. These lasers have shown respectable operating lifetimes over 3100 h. To exploit the 1550 nm telecom wavelength where long-distance communication can benefit from the least attenuation, developing InP-based QD lasers on silicon is necessary. In this work, optically pumped subwavelength InAs/In(Al)GaAs quantum dot microdisk lasers (MDLs) epitaxially grown on CMOS-compatible (001) silicon emitting at 1.55 lm are reported.…”
mentioning
confidence: 99%