The essential functionality of photonic and electronic devices is contained in thin surface layers leaving the substrate often to play primarily a mechanical role. Layer transfer of optimised devices or materials and their heterogeneous integration is thus a very attractive strategy to realise high performance, low-cost circuits for a wide variety of new applications. Additionally, new device configurations can be achieved that could not otherwise be realised. A range of layer transfer methods have been developed over the years including epitaxial lift-off and wafer bonding with substrate removal. Recently, a new technique called transfer printing has been introduced which allows manipulation of small and thin materials along with devices o...
Transfer printing is an enabling technology for the efficient integration of III-V semiconductor dev...
We present a recently invented approach to combine broad classes of dissimilar materials into hetero...
We report on the heterogeneous integration of electrically pumped InP Fabry-Perot lasers on a SOI ph...
Transfer printing is becoming widely adopted as a back-end process for the hybrid integration of pho...
Transfer-printing provides a highly versatile methodology to heterogeneously and intimately integrat...
Separating the substrate allows thin layers of III-V photonic semiconductor materials and devices to...
Micro-transfer-printing is a key enabling technology for the heterogeneous integration of different ...
Micro-transfer-printing enables the intimate integration of a wide range of opto-electronic micro-co...
Silicon photonics (SiPh) is a disruptive technology in the field of integrated photonics and has exp...
The heterogeneous integration of devices from multiple material platforms onto a single chip is demo...
Optical systems require the integration of technologies fabricated on different materials. We use a ...
Photonic integrated circuits (PICs), implementing optical functions such as light generation, modula...
For the first time, III-V opto-electronic components are coupled to silicon waveguide circuits using...
The vertical micro-assembly of membrane photonic devices across a range of materials is presented, i...
We present a transfer printing technique with sub-100nm absolute placement accuracy. Hybrid integrat...
Transfer printing is an enabling technology for the efficient integration of III-V semiconductor dev...
We present a recently invented approach to combine broad classes of dissimilar materials into hetero...
We report on the heterogeneous integration of electrically pumped InP Fabry-Perot lasers on a SOI ph...
Transfer printing is becoming widely adopted as a back-end process for the hybrid integration of pho...
Transfer-printing provides a highly versatile methodology to heterogeneously and intimately integrat...
Separating the substrate allows thin layers of III-V photonic semiconductor materials and devices to...
Micro-transfer-printing is a key enabling technology for the heterogeneous integration of different ...
Micro-transfer-printing enables the intimate integration of a wide range of opto-electronic micro-co...
Silicon photonics (SiPh) is a disruptive technology in the field of integrated photonics and has exp...
The heterogeneous integration of devices from multiple material platforms onto a single chip is demo...
Optical systems require the integration of technologies fabricated on different materials. We use a ...
Photonic integrated circuits (PICs), implementing optical functions such as light generation, modula...
For the first time, III-V opto-electronic components are coupled to silicon waveguide circuits using...
The vertical micro-assembly of membrane photonic devices across a range of materials is presented, i...
We present a transfer printing technique with sub-100nm absolute placement accuracy. Hybrid integrat...
Transfer printing is an enabling technology for the efficient integration of III-V semiconductor dev...
We present a recently invented approach to combine broad classes of dissimilar materials into hetero...
We report on the heterogeneous integration of electrically pumped InP Fabry-Perot lasers on a SOI ph...