The present disclosure describes a throughput-scalable photon sensing system. The system includes a plurality of semiconductor dies sharing a common semiconductor substrate and a plurality of photon detection sensors configured to perform a single molecule analysis of biological or chemical samples. Two immediately neighboring photon detection sensors are arranged on respective two semiconductor dies separated by a dicing street. Each photon detection sensor is arranged on a separate semiconductor die. The system further includes a first optical waveguide, a plurality of second optical waveguides disposed above the first optical waveguide, one or more wells disposed in the plurality of second optical waveguides, and one or more light guiding channels.

A multi-cell transistor includes a semiconductor structure, a plurality of unit cell transistors that are electrically connected in parallel, each unit cell transistor extending in a first direction in the semiconductor structure, wherein the unit cell transistors are spaced apart from each other along a second direction, and an isolation structure that is positioned between a first group of the unit cell transistors and a second group of the unit cell transistors and that extends above the semiconductor structure.

A package includes an integrated circuit that includes at least one active area and at least one secondary device area, a support configured to support the integrated circuit, and a die attach material. The integrated circuit being mounted on the support using the die attach material and the die attach material including at least one channel configured to allow gases generated during curing of the die attach material to be released from the die attach material.

A method for manufacturing a semiconductor device includes a process of providing two source electrodes on a substrate, a process of providing a gate electrode on one surface of the substrate between the two source electrodes, a process of providing an insulating film on the gate electrode, the substrate, and side surfaces of the two source electrodes, a process of providing an airbridge foundation resist on the insulating film, providing an airbridge on the two source electrodes and the airbridge foundation resist, and a process of removing the airbridge foundation resist, in which surfaces of the two source electrodes at sides opposite to the substrate and a front surface of the airbridge foundation resist provided in the subsequent process are substantially coplanar.

An electrically conductive sub-collector layer is provided in a surface layer portion of a substrate. A collector layer, a base layer, and an emitter layer are located within the sub-collector layer when viewed in plan. The collector layer is connected to the sub-collector layer. An emitter electrode and a base electrode are long in a first direction when viewed in plan. The emitter electrode overlaps the emitter layer. The base electrode and the emitter electrode are discretely located away from each other in a second direction orthogonal to the first direction. A collector electrode is located on one side in the second direction with respect to the emitter electrode and is not located on the other side when viewed in plan. A base line is connected to the base electrode in a manner so as to adjoin a portion other than longitudinal ends of the base electrode.

A semiconductor device includes a substrate; a gate electrode, a source electrode, and a drain electrode, the gate electrode, the source electrode and the drain electrode being formed on the substrate; a plurality of nonconductive nanowires formed two-dimensionally on an upper surface of the substrate so as to extend perpendicularly to the upper surface of the substrate; an electrode pad formed at upper ends of the plurality of nanowires so as to have a gap between the electrode pad and the substrate, the electrode pad being supported by the plurality of nanowires; and an extraction electrode connecting the electrode pad and the gate electrode.

Packaged RF transistor amplifiers are provided that include a flat no-lead overmold package that includes a die pad, a plurality of terminal pads and an overmold encapsulation that at least partially covers the die pad and the terminal pads and an RF transistor amplifier die mounted on the die pad and at least partially covered by the overmold encapsulation. These packaged RF transistor amplifiers may have an output power density of at least 3.0 W/mm.sup.2.

A power transistor includes multiple substantially parallel transistor fingers, where each finger includes a conductive source stripe and a conductive drain stripe. The power transistor also includes multiple substantially parallel conductive connection lines, where each conductive connection line connects at least one source stripe to a common source connection or at least one drain stripe to a common drain connection. The conductive connection lines are disposed substantially perpendicular to the transistor fingers. At least one of the source or drain stripes is segmented into multiple portions, where adjacent portions are separated by a cut location having a higher electrical resistance than remaining portions of the at least one segmented source or drain stripe.

A transistor semiconductor die includes a drift layer, a first dielectric layer, a first metallization layer, a second dielectric layer, a second metallization layer, a first plurality of electrodes, and a second plurality of electrodes. The first dielectric layer is over the drift layer. The first metallization layer is over the first dielectric layer such that at least a portion of the first metallization layer provides a first contact pad. The second dielectric layer is over the first metallization layer. The second metallization layer is over the second dielectric layer such that at least a portion of the second metallization layer provides a second contact pad and the second metallization layer at least partially overlaps the first metallization layer. The transistor semiconductor die is configured to selectively conduct current between the first contact pad and a third contact pad based on signals provided at the second contact pad.

A gate pad is includes a first portion disposed in a gate pad region and a second portion disposed in a gate resistance region and connected to the first portion, the gate pad has a planar shape in which the second portion protrudes from the first portion. A gate polysilicon layer disposed on a front surface of a semiconductor substrate via a gate insulating film, between the semiconductor substrate and an interlayer insulating film, has a surface area at least equal to that of the gate pad and opposes an entire surface of the gate pad in a depth direction. ESD capability of a first region where the gate pad is provided is greater than ESD capability of a second region where a gate resistance is provided and is greater than ESD capability of a third region where a MOS structure of an active region is provided.