Silicon-Integrated Hybrid-Cavity 850-nm VCSELs by Adhesive Bonding: Impact of Bonding Interface Thickness on Laser Performance

Kumari, Sulakshna; Haglund, Erik; Gustavsson, Johan S.; Baets, Roel; Roelkens, Günther; Larsson, Anders

doi:10.1109/jstqe.2016.2633823

Cited by 20 publications

(19 citation statements)

References 19 publications

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“…These HC‐VCSELs had an output power of 1.6 mW at 845 nm and were capable of 20 Gb/s error‐free data transmission under direct current modulation . The bonding interface is found to be of high importance for the optimization of the laser performance . By choosing the thickness of the bonding interface one can either achieve minimum threshold current, maximum output power and maximum bandwidth at a specific ambient temperature or a temperature‐stable threshold current and bandwidth.…”

Section: Heterogeneously Integrated Iii‐v/si Lasersmentioning

confidence: 99%

Novel Light Source Integration Approaches for Silicon Photonics

Wang

Abbasi

Dave

et al. 2017

Laser & Photonics Reviews

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166

108

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Silicon does not emit light efficiently, therefore the integration of other light-emitting materials is highly demanded for silicon photonic integrated circuits. A number of integration approaches have been extensively explored in the past decade. Here, the most recent progress in this field is reviewed, covering the integration approaches of III-V-to-silicon bonding, transfer printing, epitaxial growth and the use of colloidal quantum dots. The basic approaches to create waveguide-coupled on-chip light sources for different application scenarios are discussed, both for silicon and silicon nitride based waveguides. A selection of recent representative device demonstrations is presented, including high speed DFB lasers, ultra-dense comb lasers, short (850nm) and long (2.3μm) wavelength lasers, wide-band LEDs, monolithic O-band lasers and micro-disk lasers operating in the visible. The challenges and opportunities of these approaches are discussed.

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Section: Heterogeneously Integrated Iii‐v/si Lasersmentioning

confidence: 99%

Novel Light Source Integration Approaches for Silicon Photonics

Wang

Abbasi

Dave

et al. 2017

Laser & Photonics Reviews

Self Cite

166

108

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“…The top half‐structure is a GaAs‐based half‐VCSEL identical to the one used in Ref. [], consisting of a top p‐doped

{Al}_{0.12} {Ga}_{0.88} As / {Al}_{0.90} {Ga}_{0.10} As

DBR with 23 mirror pairs, a 1‐λ‐thick separate confinement heterostructure (SCH) containing five 4‐nm‐thick

{In}_{0.10} {Ga}_{0.90} As / {Al}_{0.37} {Ga}_{0.63} As

quantum wells, and a 1‐λ‐thick n‐doped

{Al}_{0.12} {Ga}_{0.88} As

current spreading layer (CSL). A 30‐nm‐thick layer of

{Al}_{0.98} {Ga}_{0.02} As

is included in the DBR mirror pair closest to the SCH, for the formation of an oxide aperture via selective oxidation.…”

Section: Concept and Designmentioning

confidence: 99%

“…The bottom‐half structure is a SiN‐waveguide/dielectric‐DBR combination on a Si substrate consisting of a weak diffraction grating etched in an intra‐cavity SiN waveguide placed on top of a CMOS‐compatible 20‐pair

{Ta}_{2} O_{5}

{SiO}_{2}

dielectric bottom DBR identical to the one used in Ref. []. The top and bottom

{SiO}_{2}

cladding layers prevent the waveguide mode to leak into the high index GaAs half‐VCSEL and the high index dielectric DBR and Si substrate.…”

Section: Concept and Designmentioning

confidence: 99%

Vertical‐Cavity Silicon‐Integrated Laser with In‐Plane Waveguide Emission at 850 nm

Kumari

Haglund

Gustavsson

et al. 2018

Laser & Photonics Reviews

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A continuous‐wave electrically‐pumped short‐wavelength hybrid vertical‐cavity silicon‐integrated laser (VCSIL) with in‐plane emission into a silicon nitride (SiN) waveguide is experimentally demonstrated. The coupling from the vertical cavity into the in‐plane SiN waveguide is achieved by a weak grating on the SiN waveguide placed inside the cavity. The grating provides coupling, sets the polarization of the lasing output, and provides transverse mode control. A 5 µm oxide‐aperture diameter device with a threshold current of 1.1 mA produces 73 µW single‐sided waveguide‐coupled optical output power at 2.6 mA bias current at a wavelength of 856 nm and a side‐mode suppression ratio (SMSR) of 29 dB.

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“…Частота эффективной модуляции лазеров достигает 9 GHz, ограничена низкой паразитной частотой отсечки и саморазогревом. Длинноволновые вертикально-излучающие лазеры (ВИЛ) представ-ляют интерес для реализации оптической передачи данных не только на дальние дистанции, но и на сверхкороткие расстояния (в пределе для гибридной интеграции с кремниевыми оптическими и электрон-ными схемами) [1]. По сравнению с ВИЛ ближнего ИК-диапазона ВИЛ спектрального диапазона 1.55 µm демонстрируют более низкую потребляемую мощность и меньшие оптические потери в кремниевом оптоволокне волноводах.…”

Section: поступило в редакцию 31 июля 2017 гunclassified

Вертикально-излучающие лазеры спектрального диапазона 1.55 mum, сформированные методом спекания

Бабичев¹,

Карачинский²,

Новиков³

et al. 2018

Письма В Журнал Технической Физики

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The results of studies on fabrication of vertical-cavity surface-emitting 1.55-μm lasers by fusing AlGaAs/GaAs distributed-Bragg-reflector wafers and an active region based on thin In_0.74Ga_0.26 As quantum wells grown by molecular-beam epitaxy are presented. Lasers with a current aperture diameter of 8 μm exhibit continuous lasing with a threshold current below 1.5 mA, an output optical power of 6 mW, and an efficiency of approximately 22%. Single-mode lasing with a side-mode suppression ratio of 40–45 dB is observed in the entire operating current range. The effective modulation frequency of these lasers is as high as 9 GHz and is limited by the low parasitic cutoff frequency and self-heating.

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Silicon-Integrated Hybrid-Cavity 850-nm VCSELs by Adhesive Bonding: Impact of Bonding Interface Thickness on Laser Performance

Cited by 20 publications

References 19 publications

Novel Light Source Integration Approaches for Silicon Photonics

Novel Light Source Integration Approaches for Silicon Photonics

Vertical‐Cavity Silicon‐Integrated Laser with In‐Plane Waveguide Emission at 850 nm

Вертикально-излучающие лазеры спектрального диапазона 1.55 mum, сформированные методом спекания

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