A photosensitive field-effect transistor which can be configured to provide an electrical response when illuminated by electromagnetic radiation incident on the transistor. The field-effect transistor has a channel (13) made from a two-dimensional material and comprises a photoactive layer (22) which can be configured to donate charge carriers to the transistor channel (13) when electromagnetic radiation is absorbed in the photoactive layer (22). The photosensitive field-effect transistor comprises a top electrode (21) which is in contact with the photoactive layer on one or more contact areas which together form a contact pattern. With a suitably patterned top electrode (21), a voltage applied to the electrode can function as an electrical shutter which can switch the photosensitive field-effect transistor between a light-sensitive state and a light-immune state.

Nanostructure array optoelectronic devices are disclosed. The optoelectronic device may have one or more intermediate electrical contacts that are physically and electrically connected to sidewalls of the array of nanostructures. The contacts may allow different photo-active regions of the optoelectronic device to be independently controlled. For example, one color light may be emitted or detected independently of another using the same group of one or more nanostructures. The optoelectronic device may be a pixilated device that may serve as an LED display or imaging sensor. The pixilated device may have an array of nanostructures with alternating rows and columns of sidewall electrical contacts at different layers. A pixel may be formed at the intersection of a row contact and a column contact. As one example, a single group of one or more nanostructures has a blue sub-pixel, a green sub-pixel, and a red sub-pixel.

Nanostructure array optoelectronic devices are disclosed. The optoelectronic device may have one or more intermediate electrical contacts that are physically and electrically connected to sidewalls of the array of nanostructures. The contacts may allow different photo-active regions of the optoelectronic device to be independently controlled. For example, one color light may be emitted or detected independently of another using the same group of one or more nanostructures. The optoelectronic device may be a pixilated device that may serve as an LED display or imaging sensor. The pixilated device may have an array of nanostructures with alternating rows and columns of sidewall electrical contacts at different layers. A pixel may be formed at the intersection of a row contact and a column contact. As one example, a single group of one or more nanostructures has a blue sub-pixel, a green sub-pixel, and a red sub-pixel.

Disclosed are structures and methods of forming the structures so as to have a photodetector isolated from a substrate by stacked trench isolation regions. In one structure, a first trench isolation region is in and at the top surface of a substrate and a second trench isolation region is in the substrate below the first. A photodetector is on the substrate aligned above the first and second trench isolation regions. In another structure, a semiconductor layer is on an insulator layer and laterally surrounded by a first trench isolation region. A second trench isolation region is in and at the top surface of a substrate below the insulator layer and first trench isolation region. A photodetector is on the semiconductor layer and extends laterally onto the first trench isolation region. The stacked trench isolation regions provide sufficient isolation below the photodetector to allow for direct coupling with an off-chip optical fiber.

An electrically-powered device, structure and/or component is provided that includes an attached electrical power source in a form of a unique, environmentally-friendly energy harvesting element or component. The energy harvesting component provides a mechanism for generating autonomous renewable energy, or a renewable energy supplement, in the integrated circuit system, structure and/or component. The energy harvesting element includes a first conductor layer, a low work function layer, a dielectric layer, and a second conductor layer that are particularly configured in a manner to promote electron migration from the low work function layer, through the dielectric layer, to the facing surface of the second conductor layer in a manner that develops an electric potential between the first conductor layer and the second conductor layer. The energy harvesting component includes a plurality of energy harvesting elements electrically connected to one another to increase an electrical power output.

Provided are an optical receiver that can realize a reduction in the variation of sensitivity in the ultraviolet light region and a reduction in noise in the visible light region and the infrared light region, a portable electronic device, and a method of producing an optical receiver. The first light-receiving device (PD1) and the second light-receiving device (PD2) of the optical receiver (1) are each constituted by forming a second conductivity-type N-type well layer (N_well) on a first conductivity-type P-type substrate (P_sub), forming a first conductivity-type P-type well layer (P_well) in the N-type well layer (N_well), and forming a second conductivity-type N-type diffusion layer (N) in the P-type well layer (P_well). The P-type substrate P_sub, the N-type well layer (N_well), and the P-type well layer (P_well) are electrically at the same potential or are short-circuited.

Provided are an optical receiver that can realize a reduction in the variation of sensitivity in the ultraviolet light region and a reduction in noise in the visible light region and the infrared light region, a portable electronic device, and a method of producing an optical receiver. The first light-receiving device (PD1) and the second light-receiving device (PD2) of the optical receiver (1) are each constituted by forming a second conductivity-type N-type well layer (N_well) on a first conductivity-type P-type substrate (P_sub), forming a first conductivity-type P-type well layer (P_well) in the N-type well layer (N_well), and forming a second conductivity-type N-type diffusion layer (N) in the P-type well layer (P_well). The P-type substrate P_sub, the N-type well layer (N_well), and the P-type well layer (P_well) are electrically at the same potential or are short-circuited.

A photodetecting device for detecting different wavelengths includes a first photodetecting component including a substrate and a second photodetecting component including second absorption region. The substrate includes a first absorption region configured to absorb photons having a first peak wavelength and to generate first photo-carriers. The second absorption region is supported by the substrate and configured to absorb photons having a second peak wavelength and to generate second photo-carriers. The first absorption region and the second absorption region are overlapped along a vertical direction.

A component with a semiconductor body, and first and second metal layer is disclosed. The first metal layer is arranged between the semiconductor body and the second metal layer, the semiconductor body has a first semiconductor layer on a side which is averted from the first metal layer, a second semiconductor layer on a side facing towards the first metal layer, and an active layer arranged between the first semiconductor layer and the second semiconductor layer, the component has a through-connection, which extends through the second semiconductor layer and the active layer for the electrical bonding of the first semiconductor layer. The second metal layer has a first subregion electrically connected to the through-connection by the first metal layer, and a second subregion spaced apart laterally from the first subregion by an intermediate space. In an overhead view, the first metal layer laterally completely covers the intermediate space.

A component with a semiconductor body, and first and second metal layer is disclosed. The first metal layer is arranged between the semiconductor body and the second metal layer, the semiconductor body has a first semiconductor layer on a side which is averted from the first metal layer, a second semiconductor layer on a side facing towards the first metal layer, and an active layer arranged between the first semiconductor layer and the second semiconductor layer, the component has a through-connection, which extends through the second semiconductor layer and the active layer for the electrical bonding of the first semiconductor layer. The second metal layer has a first subregion electrically connected to the through-connection by the first metal layer, and a second subregion spaced apart laterally from the first subregion by an intermediate space. In an overhead view, the first metal layer laterally completely covers the intermediate space.