Disclosed herein are CdTe-based solar cells that are successfully removed from their glass superstrate through a combination of lamination to a backsheet followed by thermal shock.

A method for treating a solid layer includes: providing a multi-layer assembly having a carrier substrate and a solid layer bonded to the carrier substrate by a bonding layer, the solid layer having an exposed surface including a defined surface structure, the defined surface structure resulting from a removal, which is effected by a crack, from a donor substrate, at least in sections; processing the solid layer, which is arranged on the carrier substrate; and separating the solid layer from the carrier substrate by a destruction of the bonding layer.

A method for producing a layer of solid material includes: providing a solid body having opposing first and second surfaces, the second surface being part of the layer of solid material; generating defects by means of multiphoton excitation caused by at least one laser beam penetrating into the solid body via the second surface and acting in an inner structure of the solid body to generate a detachment plane, the detachment plane including regions with different concentrations of defects; providing a polymer layer on the solid body; and generating mechanical stress in the solid body such that a crack propagates in the solid body along the detachment plane and the layer of solid material separates from the solid body along the crack.

Disclosed are an array substrate and a preparation method thereof, and a digital microfluidic chip. The preparation method includes: forming a plurality of photoelectric detection devices on a silicon-based substrate; transferring the photoelectric detection devices to a base substrate by adopting a micro transfer printing process; and forming a plurality of transparent driving electrodes on the base substrate, wherein the transparent driving electrodes are insulated from the photoelectric detection devices.

An electrostatically controlled sensor includes a GaN/AlGaN heterostructure having a 2DEG channel in the GaN layer. Source and drain contacts are electrically coupled to the 2DEG channel through the AlGaN layer. A gate dielectric is formed over the AlGaN layer, and gate electrodes are formed over the gate dielectric, wherein each gate electrode extends substantially entirely between the source and drain contacts, wherein the gate electrodes are separated by one or more gaps (which also extend substantially entirely between the source and drain contacts). Each of the one or more gaps defines a corresponding sensing area between the gate electrodes for receiving an external influence. A bias voltage is applied to the gate electrodes, such that regions of the 2DEG channel below the gate electrodes are completely depleted, and regions of the 2DEG channel below the one or more gaps in the direction from source to drain are partially depleted.

The present invention relates to the epitaxial lift-off of thin-films allowing the reuse of the expensive semiconductor substrates. In particular, it describes a structure and a method for epitaxial lift-off of several thin films from a single substrate (100) using a plurality of dissimilar sacrificial layers (101), strained layers (102, 104), and/or device or component layers (103). The properties of the sacrificial layers (101) and the strained layers (102,104) can be used (i) to facilitate the lift off process, (ii) to control the point of time of release of each released thin film individually and (iii) to aid in separation and sorting of the released thin films. The released device or component layers can comprise various useful structures, such as optoelectronic devices photonic components.

The invention provides a laser rapid fabrication method for flexible gallium nitride (GaN) photodetector which comprises the following steps: (1) bonding a flexible substrate to a GaN epitaxial wafer; (2) adjusting the focal plane position of a light beam, and ensuring that the light beam is incident from the side of a GaN epitaxial wafer substrate; (3) enabling the light beam to perform scanning irradiation from the edge of a sample structure obtained in the step (1); (4) adjusting the process parameters, and scanning irradiation in the reverse direction along the path in the step (3); (5) remove the original rigid transparent substrate of the epitaxial wafer to obtain a Ga metal nanoparticle/GaN film/flexible substrate structure; and (6) preparing interdigital electrodes on the surfaces of the Ga metal nanoparticles obtained in the step (5).

The flexible GaN photodetector with Ga metal nanoparticle in-situ distribution detection surface is prepared in one step through laser technology, the process is simplified, meanwhile, the surface of the detector is induced to form the surface plasmon resonance effect, the light absorption and light response performance is greatly enhanced, and the flexible gallium nitride photodetector is suitable for industrial production.

Provided is a method of fabricating a see-through thin film solar cell, the method including preparing a substrate including a molybdenum (Mo) layer on one surface, forming see-through patterns by selectively removing at least parts of the Mo layer, sequentially depositing a chalcogenide absorber layer, a buffer layer, and a transparent electrode layer on the substrate and the Mo layer including the see-through patterns, and forming a see-through array according to a shape of the see-through patterns by removing the chalcogenide absorber layer, the buffer layer, and the transparent electrode layer deposited on the see-through patterns, by irradiating a laser beam from under the substrate toward the transparent electrode layer.

In order to enable simple removal of a substrate used for manufacturing a semiconductor element, a manufacturing method includes forming a graphene layer on a substrate portion formed of a semiconductor, forming an element portion on the graphene layer, the element portion including a semiconductor layer directly formed on the graphene layer, which takes over crystal information relating to the substrate portion when the semiconductor layer is formed on the substrate portion without intermediation of the graphene layer, and performing cutting-off between the substrate portion and the element portion at the graphene layer.

The present application provides a method for manufacturing a monocrystalline silicon sheet, including: cutting a monocrystalline silicon rod along a radial or an axial direction of the monocrystalline silicon rod to obtain a monocrystalline silicon substrate; etching a porous silicon structure on a top surface and a bottom surface of the monocrystalline silicon substrate by wet etching; depositing a monocrystalline silicon thin layer on the porous silicon structure by chemical vapor deposition, so that a thickness of the monocrystalline silicon thin layer reaches a predetermined value; and striping the monocrystalline silicon thin layer from the porous silicon structure to obtain the monocrystalline silicon sheet. In the present application, the production capacity of directly manufacturing a single crystal silicon wafer by a chemical vapor deposition method can be improved, and a process for manufacturing a silicon wafer is combined with the process of a diffusion emitter conventionally belonging to cell manufacturing, so that a manufacturing cost of a solar monocrystalline silicon cell is significantly reduced.