Provided are opto-electronic devices with low dark noise and high signal-to-noise ratio and methods of manufacturing the same. An opto-electronic device may include: a semiconductor substrate; a light receiving unit formed in the semiconductor substrate; and a driving circuit arranged on a surface of the semiconductor substrate. The light receiving unit may include: a first semiconductor layer partially arranged in an upper region of the semiconductor substrate and doped with a first conductivity type impurity; a second semiconductor layer arranged on the first semiconductor layer and doped with a second conductivity type impurity; a transparent matrix layer arranged on an upper surface of the second semiconductor layer; a plurality of quantum dots arranged to contact the transparent matrix layer; and a first electrode and a second electrode electrically connected to the second semiconductor layer and respectively arranged on both sides of the transparent matrix layer.

An image sensing device includes a substrate structured to include a first surface on a first side of the substrate and a second surface on a second side of the substrate opposite to the first side and to further include a first active region and a second active region in a portion of the substrate near the second surface, at least one photoelectric conversion element formed in the substrate, and structured to generate photocharges by performing photoelectric conversion of incident light received through the first surface of the substrate, a floating diffusion region formed near the second surface of the substrate, and structured to receive the photocharges from the photoelectric conversion element and temporarily store the received photocharges, a transistor formed in the first active region, and structured to include a first source/drain region coupled to the floating diffusion region, and a well pickup region formed in the second active region, and structured to apply a bias voltage to the substrate. The first source/drain region and the well pickup region have complementary conductivities and are formed to be in contact with each other.

The invention concerns a detector arrangement for detection of radiation, in particular particle radiation or electromagnetic radiation, with a semi-conductor detector with several pixels for detection of the radiation. It is proposed that the individual pixels each have a first subpixel (1) and a second subpixel (2). The semi-conductor detector can be switched between a first collection state, in which the first subpixel (1) is sensitive and the second subpixel (2) is insensitive so that radiation-generated signal charge carriers are substantially collected only in the first subpixel (1), and a second collection state in which the second subpixel (2) is sensitive and the first subpixel (1) is insensitive so that the radiation-generated signal charge carriers are collected substantially only in the second subpixel (2). The invention furthermore concerns a corresponding operating method and detector arrangements based on the same concept with a higher number of subpixels per pixel.

An imaging device includes: a semiconductor layer including a first region of a first conductivity, a second region of a second conductivity opposite to the first conductivity, and a third region of the second conductivity; a photoelectric converter electrically connected to the first region and converting light into charge; a first transistor including a first source, a first drain, and a first gate above the second region, the first region corresponding to the first source or drain; and a second transistor including a second source, a second drain, and a second gate of the second conductivity above the third region, the first region corresponding to the second source or drain, and the second gate being electrically connected to the first region. The concentration of an impurity of the second conductivity in the third region is higher than that of an impurity of the second conductivity in the second region.

The present technology relates to a solid-state imaging device and an electronic device for increasing the degree of freedom regarding arrangement of transistors. Provided are a photoelectric conversion unit, a trench penetrating a semiconductor substrate in a depth direction and formed between the photoelectric conversion units respectively formed in adjacent pixels, and a PN junction region configured by a P-type region and an N-type region on a sidewall of the trench, in which a part of sides surrounding the photoelectric conversion unit includes a region where the P-type region is not formed or a region where the P-type region is thinly formed. The PN junction region is formed on at least one side of four sides surrounding the photoelectric conversion unit, and the P-type region is not formed on the remaining sides. The present technology can be applied to, for example, a back-illuminated-type CMOS image sensor.

Some embodiments provide an image sensor pixel comprising a junction field effect transistor (JFET) and a floating diffusion configured to act as the gate of the JFET. An image sensor may comprise a plurality of pixels, at least one pixel comprising floating diffusion region formed in a semiconductor substrate, a transfer gate configured to selectively cause transfer of photocharge stored in the pixel to the floating diffusion, and a JFET having (i) a source and a drain coupled by a channel region, and (ii) a gate comprising the floating diffusion region.

An image sensing device includes a substrate structured to include a first surface on a first side of the substrate and a second surface on a second side of the substrate opposite to the first side and to further include a first active region and a second active region in a portion of the substrate near the second surface, at least one photoelectric conversion element formed in the substrate, and structured to generate photocharges by performing photoelectric conversion of incident light received through the first surface of the substrate, a floating diffusion region formed near the second surface of the substrate, and structured to receive the photocharges from the photoelectric conversion element and temporarily store the received photocharges, a transistor formed in the first active region, and structured to include a first source/drain region coupled to the floating diffusion region, and a well pickup region formed in the second active region, and structured to apply a bias voltage to the substrate. The first source/drain region and the well pickup region have complementary conductivities and are formed to be in contact with each other.

Provided are a light-receiving element which has more capability of detecting wavelengths than that of existing silicon light-receiving elements and a unit pixel of an image sensor by using it. The light-receiving element includes: a light-receiving unit which is floated or connected to external voltage and absorbs light; an oxide film which is formed to come in contact with a side of the light-receiving unit; a source and a drain which stand off the light-receiving unit with the oxide film in between and face each other; a channel which is formed between the source and the drain and forms an electric current between the source and the drain; and a wavelength expanding layer which is formed in at least one among the light-receiving unit, the oxide film and the channel and forms a plurality of local energy levels by using strained silicon.

An opto-electronic device includes a base portion, a first electrode and a second electrode formed on an upper surface of the base portion apart from each other, a quantum dot layer, and a bank structure. The quantum dot layer is between the first electrode and the second electrode on the base portion and includes a plurality of quantum dots. The bank structure covers at least partial regions of the first electrode and the second electrode, defines a region where the quantum dot layer is formed, and is formed of an inorganic material.

Germanium-based sensors are disclosed herein. An exemplary germanium-based sensor includes a germanium photodiode and a junction field effect transistor (JFET) formed from a germanium layer disposed in a silicon substrate, in some embodiments, or on a silicon substrate, in some embodiments. A doped silicon layer, which can be formed by in-situ doping epitaxially grown silicon, is disposed between the germanium layer and the silicon substrate. In embodiments where the germanium layer on the silicon substrate, the doped silicon layer is disposed between the germanium layer and an oxide layer. The JFET has a doped polysilicon gate, and in some embodiments, a gate diffusion region is disposed in the germanium layer under the doped polysilicon gate. In some embodiments, a pinned photodiode passivation layer is disposed in the germanium layer. In some embodiments, a pair doped region pair in the germanium layer is configured as an e-lens of the germanium-based sensor.