A laser-assisted microfluidics manufacturing process has been developed for the fabrication of additively manufactured structures. Roll-to-roll manufacturing is enhanced by the use of a laser-assisted electrospray printhead positioned above the flexible substrate. The laser electrospray printhead sprays microdroplets containing nanoparticles onto the substrate to form both thin-film and structural layers. As the substrate moves, the nanoparticles are sintered using a laser beam directed by the laser electrospray printhead onto the substrate.

A photo-sensitive device includes a uniform layer, a gradated buffer layer over the uniform layer, a silicon layer over the gradated buffer layer, a photo-sensitive light-sensing region in the uniform layer and the silicon layer, a device layer on the silicon layer, and a carrier wafer bonded to the device layer.

An avalanche photodiode includes a silicon layer on a substrate; a germanium layer on the silicon layer; a cathode and an anode on any of the silicon layer and the germanium layer; and a plurality of contacts on the germanium layer, in addition to the cathode and the anode. The silicon layer can include a highly doped region at each end, an intrinsic doped region in a middle, and an intermediately doped region between the highly doped region at each end and the intrinsic doped region, and the cathode and the anode are each at a respective a highly doped region at each end. The germanium layer can include a plurality of highly doped regions with each including one of the plurality of contacts.

An electrical device includes a counterdoped heterojunction selected from a group consisting of a pn junction or a p-i-n junction. The counterdoped junction includes a first semiconductor doped with one or more n-type primary dopant species and a second semiconductor doped with one or more p-type primary dopant species. The device also includes a first counterdoped component selected from a group consisting of the first semiconductor and the second semiconductor. The first counterdoped component is counterdoped with one or more counterdopant species that have a polarity opposite to the polarity of the primary dopant included in the first counterdoped component. Additionally, a level of the n-type primary dopant, p-type primary dopant, and the one or more counterdopant is selected to the counterdoped heterojunction provides amplification by a phonon assisted mechanism and the amplification has an onset voltage less than 1 V.

A photodetector is provided. The photodetector includes a bottom electrode region in a semiconductor layer, a light absorption material in the semiconductor layer, and a first buffer layer sandwiched between a bottom surface of the light absorption material and the semiconductor layer. The first buffer layer includes, from bottom to top, a first Si layer, a first SiGe layer, a second Si layer, and a second SiGe layer. A first atomic percentage of Ge in the first SiGe layer is less than a second atomic percentage of Ge in the second SiGe layer. The photodetector further includes a top electrode region over the light absorption material.

A photovoltaic device and method include a substrate coupled to an emitter side structure on a first side of the substrate and a back side structure on a side opposite the first side of the substrate. The emitter side structure or the back side structure include layers alternating between wide band gap layers and narrow band gap layers to provide a multilayer contact with an effectively increased band offset with the substrate and/or an effectively higher doping level over a single material contact. An emitter contact is coupled to the emitter side structure on a light collecting end portion of the device. A back contact is coupled to the back side structure opposite the light collecting end portion.

This invention describes a field-effect transistor in which the channel is formed in an array of quantum dots. In one embodiment the quantum dots are cladded with a thin layer serving as an energy barrier. The quantum dot channel (QDC) may consist of one or more layers of cladded dots. These dots are realized on a single or polycrystalline substrate. When QDC FETs are realized on polycrystalline or nanocrystalline thin films they may yield higher mobility than in conventional nano- or microcrystalline thin films. These FETs can be used as thin film transistors (TFTs) in a variety of applications. In another embodiment QDC-FETs are combined with: (a) coupled quantum well SWS channels, (b) quantum dot gate 3-state like FETs, and (c) quantum dot gate nonvolatile memories.

A semiconductor device having a highly doped quantum structure emitter is disclosed. In an embodiment, the semiconductor device includes a quantum structure emitter. The quantum structure emitter includes of a first layer made of an undoped semiconductor material with a large band gap, a second, middle, highly doped layer made of a semiconductor material with a low band gap and a third, undoped layer made of a semiconductor material with a large band gap.

A photodetector is provided. The photodetector includes a bottom electrode region in a semiconductor layer, a light absorption material in the semiconductor layer, and a first buffer layer sandwiched between a bottom surface of the light absorption material and the semiconductor layer. The first buffer layer includes, from bottom to top, a first Si layer, a first SiGe layer, a second Si layer, and a second SiGe layer. A first atomic percentage of Ge in the first SiGe layer is less than a second atomic percentage of Ge in the second SiGe layer. The photodetector further includes a top electrode region over the light absorption material.

The present disclosure provides a photo sensing device, the photo sensing device includes a substrate, including a silicon layer at a front surface, a photosensitive member extending into and at least partially surrounded by the silicon layer, a first doped region having a first conductivity type at a first side of the photosensitive member, wherein the first doped region is in the silicon layer, and a second doped region having a second conductivity type different from the first conductivity type at a second side of the photosensitive member opposite to the first side, wherein the second doped region is in the silicon layer, and the first doped region is apart from the second doped region, and a superlattice layer disposed between the photosensitive member and the silicon layer, wherein the superlattice layer includes a first material and a second material different from the first material.