According to some embodiments, a power system includes a solar cell, a redox flow battery arranged in a stack with the solar cell, and a shared electrode in the stack shared by the solar cell and the redox flow battery. According to some embodiments, a method includes arranging a solar cell in a stack with a redox flow battery, and providing a shared electrode in the stack shared by the solar cell and the redox flow battery.

The present disclosure provides an integrated circuit (IC) structure with a solar cell and an image sensor array. An integrated structure according to the present disclosure includes a first substrate including a plurality of photodiodes, an interconnect structure disposed on the first substrate, a first bonding layer disposed on the interconnect structure, a second bonding layer disposed on the first bonding layer, a second substrate disposed on the second bonding layer, and a transparent conductive oxide layer disposed on the second substrate.

The present disclosure provides an integrated circuit (IC) structure with a solar cell and an image sensor array. An integrated structure according to the present disclosure includes a first substrate including a plurality of photodiodes, an interconnect structure disposed on the first substrate, a first bonding layer disposed on the interconnect structure, a second bonding layer disposed on the first bonding layer, a second substrate disposed on the second bonding layer, and a transparent conductive oxide layer disposed on the second substrate.

An energy storage device comprising one or more solid state dielectric layers for use as a high-density electrical energy storage device.

An energy storage device comprising one or more solid state dielectric layers for use as a high-density electrical energy storage device.

The present disclosure provides an integrated circuit (IC) structure with a solar cell and an image sensor array. An integrated structure according to the present disclosure includes a first substrate including a plurality of photodiodes, an interconnect structure disposed on the first substrate, a first bonding layer disposed on the interconnect structure, a second bonding layer disposed on the first bonding layer, a second substrate disposed on the second bonding layer, and a transparent conductive oxide layer disposed on the second substrate.

The present invention relates to an electrochemical device, comprising a negative electrode comprising a nitrogen-containing electron storage material, a positive electrode, and an electrolyte, wherein the nitrogen-containing electron storage material has a two-dimensional or a three-dimensional covalent structure, contains heptazine and/or triazine moieties, and is capable of intercalating and de-intercalating cations. The present invention is further directed to a uses the material, a photorechargeable battery, an autophotorechargeable battery, a redox-flow-battery, a method for harvesting light and storing electrical energy, a method for detecting and removing oxygen, and a method for detecting light.

The present disclosure provides a semiconductor structure and a method of manufacturing the same. The semiconductor structure includes a sensing device, a solar cell, and an interconnecting structure. The solar cell is disposed above the sensing device and is electrically connected to the sensing device. The interconnecting structure is disposed between the sensing device and the solar cell and has a first surface facing the solar cell and a second surface facing the sensing devices. The interconnecting structure comprises a first energy storage component and a second energy storage component. The first energy storage component is disposed closer to the first surface of the interconnecting structure than the second energy storage component.

The present disclosure provides a semiconductor structure and a method of manufacturing the same. The semiconductor structure includes a sensing device, a solar cell, and an interconnecting structure. The solar cell is disposed above the sensing device and is electrically connected to the sensing device. The interconnecting structure is disposed between the sensing device and the solar cell and has a first surface facing the solar cell and a second surface facing the sensing devices. The interconnecting structure comprises a first energy storage component and a second energy storage component. The first energy storage component is disposed closer to the first surface of the interconnecting structure than the second energy storage component.

The present disclosure provides a semiconductor structure and a method of manufacturing the same. The semiconductor structure includes a sensing device, a solar cell, and an interconnecting structure. The solar cell is disposed above the sensing device and is electrically connected to the sensing device. The interconnecting structure is disposed between the sensing device and the solar cell and has a first surface facing the solar cell and a second surface facing the sensing devices. The interconnecting structure comprises a first energy storage component and a second energy storage component. The first energy storage component is disposed closer to the first surface of the interconnecting structure than the second energy storage component.