A semiconductor device, a back-side deep trench isolation (BDTI) structure of a semiconductor device, and method of manufacturing a semiconductor structure are provided. The method of manufacturing a semiconductor structure includes providing a substrate; forming one or more trenches extending from a first side of the substrate to positions within the substrate; forming a ferroelectric layer along a sidewall and a bottom of each of the one or more trenches; and forming a cap layer over the ferroelectric layer; and annealing the ferroelectric layer and the cap layer, wherein the ferroelectric layer includes one or more ferroelectric materials and the cap layer includes metals, metal nitrides or combinations thereof.

A boron (B) layer may be formed as a passivation layer in a recess in which a vertical transfer gate is to be formed. The recess may then be filled with a gate electrode of the vertical transfer gate over the passivation layer (and/or one or more intervening layers) to form the vertical transfer gate. The passivation layer may be formed in the recess by epitaxial growth. The use of epitaxy to grow the passivation layer enables precise control over the profile, uniformity, and boron concentration in the passivation layer. Moreover, the use of epitaxy to grow the passivation layer may reduce the diffusion length of the passivation layer into the substrate of the pixel sensor, which provides increased area in the pixel sensor for the photodiode.

Disclosed herein is a method of producing an infrared detector. In certain embodiments, the method includes: forming a planar multi-layer structure including an absorber including a superlattice structure; patterning the planar multi-layer structure; etching the planar multi-layer structure to define a plurality of pixels, the sidewalls of the plurality of pixels includes a sidewall roughness and multiple types of surface oxides; and performing a surface treatment process to the plurality of pixels in order to reduce the sidewall roughness and replace the surface oxides with a chlorinated surface morphology. The surface treatment process may reduce surface current of the infrared detector which may decrease the dark current in the infrared detector.

Disclosed in one example is an apparatus including a substrate, a sensor over the substrate including an active surface and a sensor bond pad, a molding layer over the substrate and covering sides of the sensor, the molding layer having a molding height relative to a top surface of the substrate that is greater than a height of the active surface of the sensor relative to the top surface of the substrate, and a lidding layer over the molding layer and over the active surface. The lidding layer and the molding layer form a space over the active surface of the sensor that defines a flow channel.

Various embodiments of the present disclosure are directed towards an image sensor having a photodetector disposed in a semiconductor substrate. The photodetector comprises a first doped region comprising a first dopant having a first doping type. A deep well region extends from a back-side surface of the semiconductor substrate to a top surface of the first doped region. A second doped region is disposed within the semiconductor substrate and abuts the first doped region. The second doped region and the deep well region comprise a second dopant having a second doping type opposite the first doping type. An isolation structure is disposed within the semiconductor substrate. The isolation structure extends from the back-side surface of the semiconductor substrate to a point below the back-side surface. A doped liner is disposed between the isolation structure and the second doped region. The doped liner comprises the second dopant.

An image sensor device includes a semiconductor substrate having a first side, and a trench isolation structure dividing the substrate into sensing units. Each sensing unit includes a first gate electrode and a second gate electrode disposed on the first side, and a first pixel and a second pixel extending into the substrate and disposed between the first and second gate electrodes from a top view perspective. The first pixel is disposed under the second pixel and electrically connected to the first gate electrode, and the second pixel is electrically connected to the second gate electrode. A method of manufacturing a semiconductor structure includes forming a trench isolation in a semiconductor substrate; forming a first pixel in the substrate; forming a second pixel in the substrate over the first pixel; forming a first gate structure over the substrate; and forming a second gate structure over the second pixel.

A boron (B) layer may be formed as a passivation layer in a recess in which a vertical transfer gate is to be formed. The recess may then be filled with a gate electrode of the vertical transfer gate over the passivation layer (and/or one or more intervening layers) to form the vertical transfer gate. The passivation layer may be formed in the recess by epitaxial growth. The use of epitaxy to grow the passivation layer enables precise control over the profile, uniformity, and boron concentration in the passivation layer. Moreover, the use of epitaxy to grow the passivation layer may reduce the diffusion length of the passivation layer into the substrate of the pixel sensor, which provides increased area in the pixel sensor for the photodiode.

A Deep Trench Isolation (DTI) structure is disclosed. The DTI structures according to embodiments of the present disclosure include a composite passivation layer. In some embodiments, the composite passivation layer includes a hole accumulation layer and a defect repairing layer. The defect repairing layer is disposed between the hole accumulation layer and a semiconductor substrate in which the DTI structure is formed. The defect repairing layer reduces lattice defects in the interface, thus, reducing the density of interface trap (DIT) at the interface. Reduced density of interface trap facilitates strong hole accumulation, thus increasing the flat band voltage. In some embodiments, the hole accumulation layer according to the present disclosure is enhanced by an oxidization treatment.

A method of fabricating a semiconductor device includes receiving a device substrate; forming an interconnect structure on a front side of the device substrate; and etching a recess into a backside of the device substrate until a portion of the interconnect structure is exposed. The recess has a recess depth and an edge of the recess is defined by a sidewall of the device substrate. A conductive bond pad is formed in the recess, and a first plurality of layers cover the conductive bond pad, extend along the sidewall of the device substrate, and cover the backside of the device substrate. The first plurality of layers collectively have a first total thickness that is less than the recess depth. A first chemical mechanical planarization is performed to remove portions of the first plurality of layers so remaining portions of the first plurality of layers cover the conductive bond pad.

A photoelectric conversion apparatus includes a semiconductor layer including an avalanche photodiode. The avalanche photodiode includes a first semiconductor region provided at a first depth position, a second semiconductor region located closer to the second surface than the first semiconductor region, a third semiconductor region that is located closer to the second surface than the second semiconductor region, is in contact with a contact plug to which a first voltage is applied, and is provided to a second depth position, a region that is in contact with a contact plug to which a second voltage is applied and provided to a third depth position, and a fourth semiconductor region provided between the region and the third semiconductor region. The photoelectric conversion apparatus includes a dielectric member including at least a portion located on a portion overlapping the fourth semiconductor region and extending over the third depth position.