A package includes an interposer substrate having at least one through-substrate via (TSV) electrically connecting a top surface of the interposer substrate to a bottom surface of the interposer substrate. The package further includes at least one semiconductor die having a top side, a bottom side, and a sidewall. The at least one semiconductor die is disposed on the interposer substrate with the bottom side electrically coupled to the top surface of the interposer substrate. A molding material is disposed on at least on a portion of the at least one semiconductor die, and an array of conductive material is disposed on the bottom surface of the interposer substrate. The array of conductive material forms the external contacts of the package.

Disclosed herein is a method comprising: forming a doped region of a semiconductor substrate by doping a surface of the semiconductor substrate with dopants; driving the dopants into the semiconductor substrate by annealing the semiconductor substrate; controlling doping profile of the doped region by repeating doping and annealing the semiconductor substrate; forming a first electrode on the semiconductor substrate, wherein the first electrode is in electrical contact with the doped region; forming an outer electrode arranged around the first electrode, wherein the outer electrode is electrically insulated from the first electrode.

Disclosed herein is an apparatus suitable for radiation detection. The apparatus may comprise a radiation absorption layer and a first electrode on the radiation absorption layer. The radiation absorption layer may be configured to generate charge carriers therein from a radiation particle absorbed by the radiation absorption layer. The first electrode may be configured to generate an electric field in the radiation absorption layer. The first electrode may have a geometry shaping the electric field so that the electric field in an amplification region of the radiation absorption layer has a field strength sufficient to cause an avalanche of the charge carriers in the amplification region.

An image sensor includes a semiconductor substrate and a multilayer film. The semiconductor substrate includes a photodiode and a back surface having a recessed region that surrounds the photodiode. The multilayer film is on, and conformal to, the recessed region, and includes N layer-groups of adjacent high-κ material layers. Each pair of adjacent high-κ material layers of a same layer-group of the N layer-groups includes (i) an outer-layer having an outer fixed-charge density and (ii) an inner-layer, located between the outer-layer and the recessed region, that has an inner fixed-charge density. Each of the outer and inner fixed-charge density is negative. The inner fixed-charge density is more negative than the outer fixed-charge density.

A pixel cell, a method for manufacturing the same and an image sensor including the same are provided. The pixel cell includes: a substrate; a photodiode, a pass transistor and a floating diffusion structure respectively formed on the substrate, in which the pass transistor is formed between the photodiode and the floating diffusion structure; and a PINNED structure, formed on the substrate and connected with the floating diffusion structure, in which a reset voltage of the floating diffusion structure is higher than a depletion voltage of the PINNED structure.

A method of fabricating a solid state radiation detector method includes mechanically lapping and polishing the first and the second surfaces of a semiconductor wafer using a plurality of lapping and polishing steps. The method also includes growing passivation oxide layers by use of oxygen plasma on the top of the polished first and second surfaces in order to passivate the semiconductor wafer. Anode contacts are deposited and patterned on top of the first passivation oxide layer, which is on top of the first surface. Cathode contacts, which are either monolithic or patterned, are deposited on top of the second passivation oxide layer, which is on the second surface. Aluminum nitride encapsulation layer can be deposited over the anode contacts and patterned to encapsulate the first passivation oxide layer, while physically exposing a center portion of each anode contact to electrically connect the anode contacts.

Object is to prevent deterioration in pixel characteristics due to dark-time white spot defects in a pixel. Generation of these dark-time white spot defects is attributable to diffusion of electrons and Fe (iron) from the vicinity of an interface between a semiconductor substrate and an element isolation region obtained by filling a trench formed in the upper surface of the semiconductor substrate with an insulating film. A semiconductor layer is formed by forming, in the upper surface of a semiconductor substrate, a trench for filling it with an element isolation region surrounding a photodiode formation region; and carrying out plasma doping to introduce B (boron) into the side wall and bottom surface of the trench.

To protect a plurality of semiconductor chips of a sawn wafer housed in a shipping case and a method of manufacturing a semiconductor device includes a step of vacuum packing a sawn wafer while being housed in a shipping case; the shipping case has the following structure: the shipping case has a lid portion that covers the upper surface of the sawn wafer and a body portion that covers the lower surface of the sawn wafer, the lid portion has a recess portion that covers a plurality of semiconductor chips and a ventilation route communicated with the recess portion. In a step of reducing pressure in the shipping case, a gas in the shipping case is discharged outside via a ventilation route.

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.

Apparatus and methods for effective impurity gettering are described herein. In some embodiments, a described device includes: a substrate; a pixel region disposed in the substrate; an isolation region disposed in the substrate and within a proximity of the pixel region; and a heterogeneous layer on the seed area. The isolation region comprises a seed area including a first semiconductor material. The heterogeneous layer comprises a second semiconductor material that has a lattice constant different from that of the first semiconductor material.