A photovoltaic device includes: a silicon substrate having a front surface having a texture; and an amorphous silicon layer having an uneven surface corresponding to the texture, wherein the amorphous silicon layer is amorphous in peak portions and slope portions extending between the peak portions and valley portions of the uneven surface, and has crystalline regions which grow, in a pillar manner, approximately perpendicularly from a substrate surface of the silicon substrate in the valley portions, the crystalline regions being discretely present along upper ends of the valley portions, the upper ends being opposite lower ends of the valley portions, the lower ends being in contact with the silicon substrate, wherein coverage of the crystalline regions in the valley portions is higher than coverage of amorphous regions in the valley portions.

A solar cell includes: a semiconductor substrate formed of n-type crystalline silicon; a first stack formed of amorphous silicon in a first region on a first principle surface of the semiconductor substrate; a second stack formed of amorphous silicon in a second region different from the first region on the first principle surface; and a third stack formed of amorphous silicon on a second principle surface of the semiconductor substrate opposite from the first principle surface. The second stack has an oxygen concentration that is higher than that of the first stack.

Provided is a field shaping multi-well photomultiplier and method for fabrication thereof. The photomultiplier includes a field-shaping multi-well avalanche detector, including a lower insulator, an a-Se photoconductive layer and an upper insulator. The a-Se photoconductive layer is positioned between the lower insulator and the upper insulator. A light interaction region, an avalanche region, and a collection region are provided along a length of the photomultiplier, and the light interaction region and the collection region are positioned on opposite sides of the avalanche region.

Provided is a field shaping multi-well photomultiplier and method for fabrication thereof. The photomultiplier includes a field-shaping multi-well avalanche detector, including a lower insulator, an a-Se photoconductive layer and an upper insulator. The a-Se photoconductive layer is positioned between the lower insulator and the upper insulator. A light interaction region, an avalanche region, and a collection region are provided along a length of the photomultiplier, and the light interaction region and the collection region are positioned on opposite sides of the avalanche region.

One or more systems and/or methods are disclosed for building a relief print generator with no bezel. An electrode layer having more than one electrode can be used in an electrode-based, electro-luminescence component of the relief print generator. The respective electrodes may be connected to power sources with different voltage phases. An electrical circuit can be created between a biometric object and more than one electrode in the electrode layer when the biometric object contacts a surface of the generator. The electro-luminescent component can be activated by electrical charge and emit light indicative of a relief print of the biometric object. A contact electrode outside the electrode layer may not be used, which may allow for the removal of a bezel from an example device.

An imaging device includes a photoelectric conversion unit in which a first electrode, a photoelectric conversion layer, and a second electrode are stacked. A semiconductor material layer including an inorganic oxide semiconductor material having an amorphous structure at least in a portion is formed between the first electrode and the photoelectric conversion layer, and the formation energy of an inorganic oxide semiconductor material that has the same composition as the inorganic oxide semiconductor material having an amorphous structure and has a crystalline structure has a positive value.

An imaging device includes a photoelectric conversion unit in which a first electrode, a photoelectric conversion layer, and a second electrode are stacked. A semiconductor material layer including an inorganic oxide semiconductor material having an amorphous structure at least in a portion is formed between the first electrode and the photoelectric conversion layer, and the formation energy of an inorganic oxide semiconductor material that has the same composition as the inorganic oxide semiconductor material having an amorphous structure and has a crystalline structure has a positive value.

Provided is a field shaping multi-well detector and method of fabrication thereof. The detector is configured by depositing a pixel electrode on a substrate, depositing a first dielectric layer, depositing a first conductive grid electrode layer on the first dielectric layer, depositing a second dielectric layer on the first conductive grid electrode layer, depositing a second conductive grid electrode layer on the second dielectric layer, depositing a third dielectric layer on the second conductive grid electrode layer, depositing an etch mask on the third dielectric layer. Two pillars are formed by etching the third dielectric layer, the second conductive grid electrode layer, the second dielectric layer, the first conductive grid electrode layer, and the first dielectric layer. A well between the two pillars is formed by etching to the pixel electrode, without etching the pixel electrode, and the well is filled with a-Se.

Provided is a field shaping multi-well detector and method of fabrication thereof. The detector is configured by depositing a pixel electrode on a substrate, depositing a first dielectric layer, depositing a first conductive grid electrode layer on the first dielectric layer, depositing a second dielectric layer on the first conductive grid electrode layer, depositing a second conductive grid electrode layer on the second dielectric layer, depositing a third dielectric layer on the second conductive grid electrode layer, depositing an etch mask on the third dielectric layer. Two pillars are formed by etching the third dielectric layer, the second conductive grid electrode layer, the second dielectric layer, the first conductive grid electrode layer, and the first dielectric layer. A well between the two pillars is formed by etching to the pixel electrode, without etching the pixel electrode, and the well is filled with a-Se.

The present invention discloses a nanoparticle control and detection system and operating method thereof. The present invention controls and detects the nanoparticles in the same device. The device comprises a first transparent electrode, a photoconductive layer, a spacer which is deposed on the edge of the photoconductive layer and a second transparent electrode. The aforementioned device controls and detects the nanoparticles by applying AC/DC bias and AC/DC light source to the transparent electrode.