Add to ORKGThe epitaxial growth of III-V materials on silicon is an alternative approach to combining silicon photonics with the active laser source. Substantial progress has been made to reduce the defects created at the III-V/Si interface to a level that has a negligible impact on laser operating current and lifetime, providing quantum dot gain materials are utilized [1,2]. A number of issues remain for the integration of III-V structures with silicon, not least that of reducing the footprint and ensuring the fabrication required is as simple as possible. While the laser reflectors can be fabricated in the silicon here we focus on using the III-V material, which removes the need to have the III-V/Silicon interface and its associated losses within th...
The age of the Internet brings unprecedented challenges to the communication networks. The ever non-...
III-V Quantum-dot (QD) materials and lasers directly grown on Si platform are the most prospective c...
The ability to tailor the bandgap of III–V compound semiconductors spatially, across the wafer is hi...
The epitaxial growth of III-V materials on silicon is an alternative approach to combining silicon p...
The epitaxial growth of III-V materials on silicon is an alternative approach to combining silicon p...
InAs quantum dot ridge waveguide lasers comprising single-port multi-mode-interference-reflectors (M...
InAs quantum dot ridge waveguide lasers comprising single-port multi-mode-interference-reflectors (M...
InAs quantum dot ridge waveguide lasers comprising single-port multi-mode-interference-reflectors (M...
InAs quantum dot ridge waveguide lasers comprising single-port multi-mode-interference-reflectors (M...
With continuously growing global data traffic, silicon (Si)-based photonic integrated circuits have ...
Summary form only given. III-V lasers grown on Si is the most promising solution to light sources on...
This thesis investigates the growth, fabrication, and performance of III-V semiconductorquantum dot ...
This article presents a novel III-V on silicon laser. This work exploits the phenomenon that a passi...
This article presents a novel III-V on silicon laser. This work exploits the phenomenon that a passi...
The age of the Internet brings unprecedented challenges to the communication networks. The ever non-...
The age of the Internet brings unprecedented challenges to the communication networks. The ever non-...
III-V Quantum-dot (QD) materials and lasers directly grown on Si platform are the most prospective c...
The ability to tailor the bandgap of III–V compound semiconductors spatially, across the wafer is hi...
The epitaxial growth of III-V materials on silicon is an alternative approach to combining silicon p...
The epitaxial growth of III-V materials on silicon is an alternative approach to combining silicon p...
InAs quantum dot ridge waveguide lasers comprising single-port multi-mode-interference-reflectors (M...
InAs quantum dot ridge waveguide lasers comprising single-port multi-mode-interference-reflectors (M...
InAs quantum dot ridge waveguide lasers comprising single-port multi-mode-interference-reflectors (M...
InAs quantum dot ridge waveguide lasers comprising single-port multi-mode-interference-reflectors (M...
With continuously growing global data traffic, silicon (Si)-based photonic integrated circuits have ...
Summary form only given. III-V lasers grown on Si is the most promising solution to light sources on...
This thesis investigates the growth, fabrication, and performance of III-V semiconductorquantum dot ...
This article presents a novel III-V on silicon laser. This work exploits the phenomenon that a passi...
This article presents a novel III-V on silicon laser. This work exploits the phenomenon that a passi...
The age of the Internet brings unprecedented challenges to the communication networks. The ever non-...
The age of the Internet brings unprecedented challenges to the communication networks. The ever non-...
III-V Quantum-dot (QD) materials and lasers directly grown on Si platform are the most prospective c...
The ability to tailor the bandgap of III–V compound semiconductors spatially, across the wafer is hi...