The present disclosure provides a photodiode, a manufacturing method thereof, and a display screen. The photodiode includes: a first electrode including a first sub-part and a second sub-part disposed at an interval, wherein the second sub-part includes a first end and a second end; a connecting part disposed on the first sub-part, the first end, and a substrate corresponding to a gap between the first sub-part and the second sub-part; and a light converting part and a second electrode disposed on the second end in sequence.

Mercury cadmium telluride (MCT) dual band photodiode elements are described that include an n-type barrier region interposed between first and second p-type regions. The first p-type region is arranged to absorb different IR wavelengths to the second p-type region in order that the photodiode element can sense two IR bands. A portion of the second p-type region is type converted using ion-beam milling to produce a n-type region that interfaces with the second p-type region and the n-type barrier region.

A time of flight sensor includes at least one pixel, including: an epitaxially-grown Ge-based photosensitive structure including an upper portion and a trunk portion, a Si-based photocurrent collecting structure, a dielectric material layer arranged at least between the upper portion of the photosensitive structure and the photocurrent collecting structure, wherein the trunk portion of the photosensitive structure is arranged within an aperture in the dielectric material layer, and at least one n-contact configured to collect electrons of a photocurrent and at least one p-contact configured to collect holes of the photocurrent, the at least one n-contact and p-contact arranged in the photocurrent collecting structure.

A time of flight sensor includes at least one pixel, including: an epitaxially-grown Ge-based photosensitive structure including an upper portion and a trunk portion, a Si-based photocurrent collecting structure, a dielectric material layer arranged at least between the upper portion of the photosensitive structure and the photocurrent collecting structure, wherein the trunk portion of the photosensitive structure is arranged within an aperture in the dielectric material layer, and at least one n-contact configured to collect electrons of a photocurrent and at least one p-contact configured to collect holes of the photocurrent, the at least one n-contact and p-contact arranged in the photocurrent collecting structure.

A detection device includes a photoelectric conversion portion in which a plurality of photodiodes are arranged in a planar shape, a light source configured to irradiate the photodiodes with light, and a heating electrode provided so as to face the photoelectric conversion portion, and configured to generate heat and conduct the heat to the photoelectric conversion portion.

A detection device includes a photoelectric conversion portion in which a plurality of photodiodes are arranged in a planar shape, a light source configured to irradiate the photodiodes with light, and a heating electrode provided so as to face the photoelectric conversion portion, and configured to generate heat and conduct the heat to the photoelectric conversion portion.

A heteroepitaxial semiconductor device includes a bulk semiconductor substrate, a seed layer including a first semiconductor material, the seed layer being arranged at a first side of the bulk semiconductor substrate and including a first side facing the bulk semiconductor substrate, an opposing second side and lateral sides connecting the first and second sides, a separation layer arranged between the bulk semiconductor substrate and the seed layer, a heteroepitaxial structure grown on the second side of the seed layer and including a second semiconductor material, different from the first semiconductor material, and a dielectric material layer arranged on the seed layer and at least partially encapsulating the heteroepitaxial structure, wherein the dielectric material layer also covers the lateral sides of the seed layer.

A heteroepitaxial semiconductor device includes a bulk semiconductor substrate, a seed layer including a first semiconductor material, the seed layer being arranged at a first side of the bulk semiconductor substrate and including a first side facing the bulk semiconductor substrate, an opposing second side and lateral sides connecting the first and second sides, a separation layer arranged between the bulk semiconductor substrate and the seed layer, a heteroepitaxial structure grown on the second side of the seed layer and including a second semiconductor material, different from the first semiconductor material, and a dielectric material layer arranged on the seed layer and at least partially encapsulating the heteroepitaxial structure, wherein the dielectric material layer also covers the lateral sides of the seed layer.

The present invention provides a photodiode and a display screen. The photodiode includes a first electrode and a second electrode in order. When a direction of an incident light of the photodiode is a first direction, a material of the first electrode is a transparent conductive material, and a material of the second electrode is a metal material. When the direction of the incident light of the photodiode is a second direction, the second electrode is made of a transparent conductive material, and the first electrode is made of a metal material.

Disclosed are a photodiode element, and a sensor and an electronic device including the same. The photodiode element includes a first electrode, a second electrode facing the first electrode, a photoelectric conversion layer between the first electrode and the second electrode and having an absorption spectrum in a first wavelength spectrum, a light-emitting layer between the photoelectric conversion layer and the second electrode and having an emission peak wavelength belonging to the first wavelength spectrum, and a first charge transport layer between the photoelectric conversion layer and the light-emitting layer.