In some aspects of the invention, an n-type field-stop layer can have a total impurity of such an extent that a depletion layer spreading in response to an application of a rated voltage stops inside the n-type field-stop layer together with the total impurity of an n.sup. type drift layer. Also, the n-type field-stop layer can have a concentration gradient such that the impurity concentration of the n-type field-stop layer decreases from a p.sup.+ type collector layer toward a p-type base layer, and the diffusion depth is 20 m or more. Furthermore, an n.sup.+ type buffer layer of which the peak impurity concentration can be higher than that of the n-type field-stop layer at 610.sup.15 cm.sup.3 or more, and one-tenth or less of the peak impurity concentration of the p.sup.+ type collector layer, can be included between the n-type field-stop layer and p.sup.+ type collector layer.

A 3D semiconductor device including: a first level including a single crystal layer and a memory control circuit including first transistors and at least one cache memory unit; a first metal layer overlaying the single crystal layer; a second metal layer overlaying the first metal layer; a third metal layer overlaying the second metal layer; second transistors disposed atop the third metal layer with at least one including a metal gate; third transistors disposed atop the second transistors; a fourth metal layer atop the third transistors; a memory array including word-lines and at least four memory mini arrays, each including at least four rows by four columns of memory cells, each of the memory cells includes at least one of the second transistors or at least one of the third transistors; a connection path from the fourth metal to the third metal including a via disposed through the memory array.

A semiconductor device includes a semiconductor fin, a gate structure, source/drain structures, and a contact structure. The semiconductor fin extends from a substrate. The gate structure extends across the semiconductor fin. The source/drain structures are on opposite sides of the gate structure. The contact structure is over a first one of the source/drain structures. The contact structure includes a semiconductor contact and a metal contact over the semiconductor contact. The semiconductor contact has a higher dopant concentration than the first one of the source/drain structures. The first one of the source/drain structures includes a first portion and a second portion at opposite sides of the fin and interfacing the semiconductor contact.

A semiconductor device includes a semiconductor fin, a gate structure, source/drain structures, and a contact structure. The semiconductor fin extends from a substrate. The gate structure extends across the semiconductor fin. The source/drain structures are on opposite sides of the gate structure. The contact structure is over a first one of the source/drain structures. The contact structure includes a semiconductor contact and a metal contact over the semiconductor contact. The semiconductor contact has a higher dopant concentration than the first one of the source/drain structures. The first one of the source/drain structures includes a first portion and a second portion at opposite sides of the fin and interfacing the semiconductor contact.

A light emitting device package can include a sub-mount having a first surface, a second surface, a bottom surface and a cavity; a first layer on the first surface; a second layer on the second surface; a third layer on the bottom surface; a light emitting device on the first layer and including a supporting layer including an anti-diffusion layer, a first electrode on the supporting layer, a semiconductor light emitting structure electrically connected to the first electrode, and a second electrode electrically connected to the semiconductor light emitting structure, in which the first and second electrodes electrically connect to the first layer and the second layer, respectively, and the semiconductor light emitting structure includes a light extraction structure; an ESD property improving diode on the second surface, electrically connected to the second layer and arranged a distance apart from the light emitting device, and a lens on the sub-mount.

According to one embodiment, a method for manufacturing a semiconductor device comprises making a first opening, ion-implanting an impurity of a second conductivity type, and forming a third semiconductor layer of the second conductivity type. The first opening is made in a second semiconductor layer. The second semiconductor layer is provided on a first semiconductor layer. The first opening extends in a second direction. A dimension in a third direction of an upper part of the first opening is longer than a dimension in the third direction of a lower part of the first opening. The third direction is perpendicular to the first direction and the second direction. The impurity of the second conductivity type is ion-implanted into a side surface of the lower part of the first opening. The third semiconductor layer of the second conductivity type is formed in an interior of the first opening.

A Static Random Access Memory (SRAM) cell includes a first pull-up transistor and a first pull-down transistor, a second pull-up transistor and a second pull-down transistor, and first and second pass-gate transistors. A first buried contact electrically connects a drain region of the first pull-up transistor and gate electrodes of the second pull-up transistor and the second pull-down transistor, and includes a first metal layer formed in a region confined by spacers of a first gate layer and a first electrically conductive path formed at a level below the spacers. A second buried contact electrically connects a drain region of the second pull-up transistor and gate electrodes of the first pull-up transistor and the first pull-down transistor, and includes a second metal layer formed in a region confined by spacers of a second gate layer and a second electrically conductive path formed at the level below the spacers.

Techniques for dielectric isolation in bulk nanosheet devices are provided. In one aspect, a method of forming a nanosheet device structure with dielectric isolation includes the steps of: optionally implanting at least one dopant into a top portion of a bulk semiconductor wafer, wherein the at least one dopant is configured to increase an oxidation rate of the top portion of the bulk semiconductor wafer; forming a plurality of nanosheets as a stack on the bulk semiconductor wafer; patterning the nanosheets to form one or more nanowire stacks and one or more trenches between the nanowire stacks; forming spacers covering sidewalls of the nanowire stacks; and oxidizing the top portion of the bulk semiconductor wafer through the trenches, wherein the oxidizing step forms a dielectric isolation region in the top portion of the bulk semiconductor wafer. A nanowire FET and method for formation thereof are also provided.

A technique relates to forming a self-aligning field effect transistor. A starting punch through stopper comprising a substrate having a plurality of fins patterned thereon, an n-type field effect transistor (NFET) region, a p-type field effect transistor (PFET) region, and a center region having a boundary defect at the interface of the NFET region and the PFET region is first provided. The field effect transistor is then masked to mask the NFET region and the PFET region such that the center region is exposed. A center boundary region is then formed by etching the center region to remove the boundary defect.

Techniques for dielectric isolation in bulk nanosheet devices are provided. In one aspect, a method of forming a nanosheet device structure with dielectric isolation includes the steps of: optionally implanting at least one dopant into a top portion of a bulk semiconductor wafer, wherein the at least one dopant is configured to increase an oxidation rate of the top portion of the bulk semiconductor wafer; forming a plurality of nanosheets as a stack on the bulk semiconductor wafer; patterning the nanosheets to form one or more nanowire stacks and one or more trenches between the nanowire stacks; forming spacers covering sidewalls of the nanowire stacks; and oxidizing the top portion of the bulk semiconductor wafer through the trenches, wherein the oxidizing step forms a dielectric isolation region in the top portion of the bulk semiconductor wafer. A nanowire FET and method for formation thereof are also provided.