A blender transmits an electrical signal via a transparent film so as to detect whether a container lid is closed. The blender includes a container body receiving food; a main body provided under the container body and supporting the container body; a container lid mounted removably to the upper surface of the container body and configured to open/close the upper part of the container body; and a detection system configured to detect whether the container lid is mounted to the container body, wherein the detection system includes a transparent electrode film attached to the surface of the container body and guiding the flow of electricity. Accordingly, the transparent electrode film can transmit whether the container lid is mounted to the main body without spoiling the appearance of the container body made of a transparent material.

A sensor, a device, a system, and a method, for biometric sensing, are provided. Such a device or system includes a micro heater and a micro temperature sensor for at least active thermal sensing, which may comprise an oxide semiconductor material. The micro heater and the micro temperature sensor may be separate or combined in one pixel. The present disclosure also provides an out-cell type or an in-cell type of biometric sensor on display device, for example, an out-cell type or an in-cell type fingerprint sensor on display (FoD) device. The pixels for active thermal sensing include an oxide semiconductor material. The methods of making and the methods of using the sensors, the devices, or the system are also provided.

A sensor, a device, a system, and a method, for biometric sensing, are provided. Such a device or system includes a micro heater and a micro temperature sensor for at least active thermal sensing, which may comprise an oxide semiconductor material. The micro heater and the micro temperature sensor may be separate or combined in one pixel. The present disclosure also provides an out-cell type or an in-cell type of biometric sensor on display device, for example, an out-cell type or an in-cell type fingerprint sensor on display (FoD) device. The pixels for active thermal sensing include an oxide semiconductor material. The methods of making and the methods of using the sensors, the devices, or the system are also provided.

Provided is a light detection sensor including: a substrate including a first surface and a second surface opposite to the first surface, wherein the second surface is a light incident surface; a deep trench isolator within a deep trench in the substrate and defining a pixel area; at least one recess into the pixel area from the second surface; a transparent electrode on the second surface and an inner surface of the at least one recess; and a first insulating film between the transparent electrode and the second surface and between the transparent electrode and the inner surface of the at least one recess.

Disclosed are a solar cell and a solar cell module comprising same, the solar cell comprising: a solar cell structure having one or more hollows passing therethrough in the height direction, and a plurality of light-concentrating parts disposed in each of the one or more hollows.

A sensor, a device, a system, and a method, for biometric sensing, are provided. Such a device or system includes a micro heater and a micro temperature sensor for at least active thermal sensing, which may comprise an oxide semiconductor material. The micro heater and the micro temperature sensor may be separate or combined in one pixel. The present disclosure also provides an out-cell type or an in-cell type of biometric sensor on display device, for example, an out-cell type or an in-cell type fingerprint sensor on display (FoD) device. The pixels for active thermal sensing include an oxide semiconductor material. The methods of making and the methods of using the sensors, the devices, or the system are also provided.

A photovoltaic device includes a substrate structure and at least one Se-containing layer, such as a CdSeTe layer. A process for manufacturing the photovoltaic device includes forming the CdSeTe layer over a substrate by at least one of sputtering, evaporation deposition, CVD, chemical bath deposition process, and vapor transport deposition process. The process can also include controlling a thickness range of the Se-containing layer.

A sensor, a device, a system, and a method, for biometric sensing, are provided. Such a device or system includes a micro heater and a micro temperature sensor for at least active thermal sensing, which may comprise an oxide semiconductor material. The micro heater and the micro temperature sensor may be separate or combined in one pixel. The present disclosure also provides an out-cell type or an in-cell type of biometric sensor on display device, for example, an out-cell type or an in-cell type fingerprint sensor on display (FoD) device. The pixels for active thermal sensing include an oxide semiconductor material. The methods of making and the methods of using the sensors, the devices, or the system are also provided.

Devices, systems and methods for operating and using an optically quenchable carbon-doped gallium nitride photoconductive semiconductor switch (PCSS) are described. An example method includes illuminating a carbon-doped gallium nitride material of the photoconductive semiconductor switch with a first laser light within a first range of wavelengths to trigger the photoconductive semiconductor switch to a conductive state, turning off or blocking the first laser light, and illuminating the carbon-doped gallium nitride material with a second laser light within a second range of wavelengths to trigger the photoconductive semiconductor switch to an insulating state. In this example, the first range of wavelengths comprises an ultraviolet (UV) or a blue wavelength range, the second range of wavelengths comprises an infrared (IR) or a red wavelength range, and switching from the conductive state to the insulating state occurs within a sub-nanosecond range.

A solar cell comprises a substrate having an opposite first surface and a second surface, and the second surface has a first regions and a second regions adjacent in the first direction; a first passivation layer located on the first surface; a first doped layer and a tunnel oxide layer sequentially stacked in the first region; a first insulating layer located on a surface of the first doped layer away from the substrate; a second passivation layer located in the second region and extending to a surface of the first insulating layer away from the substrate; a second doped layer located on a surface of the second passivation layer away from the substrate, and a second insulating layer located between the second passivation layer and the first doped layer, the tunnel oxide layer in the first direction, a surface of the second insulating layer away from the substrate contacting with the first insulating layer.