FET designs that exhibit low leakage in the presence of the edge transistor phenomenon. Embodiments includes nFET designs in which the work function Φ.sub.MF of the gate structure overlying the edge transistors of the nFET is increased by forming extra P+ implant regions within at least a portion of the gate structure, thereby increasing the Vt of the edge transistors to a level that may exceed the Vt of the central conduction channel of the nFET. In some embodiments, the gate structure of the nFET is modified to increase or “flare” the effective channel length of the edge transistors relative to the length of the central conduction channel of the FET. Other methods of changing the work function Φ.sub.MF of the gate structure overlying the edge transistors are also disclosed. The methods may be adapted to fabricating pFETs by reversing or substituting material types.

Methods of bonding thin dies to substrates. In one such method, a wafer is attached to a support layer. The wafer and support layer are attached to a dicing structure and then singulated to form a plurality of semiconductor die components. Each semiconductor die component comprises a thinned die and a support layer section attached to the thinned die where each support layer section is disposed between the corresponding thinned die and the dicing structure. At least one of the semiconductor die components is then bonded to a substrate without an intervening adhesive such that the thinned die is disposed between the substrate and the support layer section. The support layer section is then removed from the thinned die.

A semiconductor device includes a semiconductor substrate with a trench, a body region under the trench with majority carrier dopants of a first type, and a transistor, including a source region under the trench with majority carrier dopants of a second type, a drain region spaced from the trench with majority carrier dopants of the second type, a gate structure in the trench proximate a channel portion of a body region, and an oxide structure in the trench proximate a side of the gate structure.

A method for manufacturing a device may include providing an ultra-high voltage (UHV) component that includes a source region and a drain region, and forming an oxide layer on a top surface of the UHV component. The method may include connecting a low voltage terminal to the source region of the UHV component, and connecting a high voltage terminal to the drain region of the UHV component. The method may include forming a shielding structure on a surface of the oxide layer provided above the drain region of the UHV component, forming a high voltage interconnection that connects to the shielding structure and to the high voltage terminal, and forming a metal routing that connects the shielding structure and the low voltage terminal.

Disclosed herein are methods for direct bonding. In some embodiments, the direct bonding method includes microwave annealing a dielectric bonding layer of a first element by exposing the dielectric bonding layer to microwave radiation and then directly bonding the dielectric bonding layer of the first element to a second element without an intervening adhesive. The bonding method also includes depositing the dielectric bonding layer on a semiconductor portion of the first element at a first temperature and microwave annealing the dielectric bonding layer at a second temperature lower than the first temperature.

A device includes a first region disposed on a substrate, a second region disposed on the first region, a third region disposed in the second region and a first terminal region disposed in the third region. The first region comprises a discontinuous layer including at least one gap portion. The at least one gap portion comprises a portion of the substrate. The first region and the second region have a first conductivity type, and the substrate, the third region and the first terminal region have a second conductivity type. The first conductivity type is different from the second conductivity type.

A method of forming a fin field effect transistor (finFET) on a substrate includes forming a fin structure on the substrate and forming a shallow trench isolation (STI) region on the substrate. First and second fin portions of the fin structure extend above a top surface of the STI region. The method further includes oxidizing the first fin portion to convert a first material of the first fin portion to a second material. The second material is different from the first material of the first fin portion and a material of the second fin portion. The method further includes forming an oxide layer on the oxidized first fin portion and the second fin portion and forming first and second polysilicon structures on the oxide layer.

A semiconductor device can include: a substrate having a first doping type; a first well region located in the substrate and having a second doping type, where the first well region is located at opposite sides of a first region of the substrate; a source region and a drain region located in the first region, where the source region has the second doping type, and the drain region has the second doping type; and a buried layer having the second doping type located in the substrate and below the first region, where the buried layer is incontact with the first well region, where the first region is surrounded by the buried layer and the first well region, and the first doping type is opposite to the second doping type.

Forming an integrated circuit, for example by first, concurrently forming a first front end of line (FEOL) layer having a first thickness and a surface contacting or facing a semiconductor substrate frontside and a second FEOL layer, having a second thickness and including a same material as the first FEOL layer and having a surface contacting or facing a semiconductor substrate backside, and second, processing the second FEOL layer to reduce the second thickness.

There is set forth herein a photonics device. The photonics device can comprise a substrate, a conductive material formation, a dielectric stack, and a barrier layer. The photonics device can transmit a light signal.