A semiconductor device includes a substrate that includes an active pattern, a channel pattern disposed on the active pattern, where the channel pattern includes a plurality of semiconductor patterns that are vertically stacked and spaced apart from each other, a source/drain pattern connected to the semiconductor patterns, and a gate electrode disposed on the semiconductor patterns. The gate electrode includes a plurality of portions that are respectively interposed between the semiconductor patterns, and the source/drain pattern includes a buffer layer in contact with the semiconductor patterns and a main layer disposed on the buffer layer. The buffer layer contains silicon germanium (SiGe) and includes a first semiconductor layer and a first reflow layer thereon. A germanium concentration of the first reflow layer is less than that of the first semiconductor layer.

Embodiments of the present disclosure relate to methods for forming a source/drain extension. In one embodiment, a method for forming an nMOS device includes forming a gate electrode and a gate spacer over a first portion of a semiconductor fin, removing a second portion of the semiconductor fin to expose a side wall and a bottom, forming a silicon arsenide (Si:As) layer on the side wall and the bottom, and forming a source/drain region on the Si:As layer. During the deposition of the Si:As layer and the formation of the source/drain region, the arsenic dopant diffuses from the Si:As layer into a third portion of the semiconductor fin located below the gate spacer, and the third portion becomes a doped source/drain extension region. By utilizing the Si:As layer, the doping of the source/drain extension region is controlled, leading to reduced contact resistance while reducing dopants diffusing into the channel region.

A semiconductor device includes a semiconductor layer having a first surface and a second surface, an element structure formed on the first surface side of the semiconductor layer and including a first conductivity type first region and a second conductivity type second region in contact with the first region, a gate electrode opposing the second region with a gate insulating film therebetween, a first conductivity type third region formed in the semiconductor layer to be in contact with the second region, and a first electrode formed on the semiconductor layer and electrically connected to the first region and the second region, in which the element structure includes a first and a second element structure, the first element structure is separated from the second region in a direction along the first surface of the semiconductor layer, and includes a second conductivity type first column layer extending in a thickness direction.

A p-type semiconductor region is formed in a front surface side of an n-type semiconductor substrate. An n-type field stop (FS) region including protons as a donor is formed in a rear surface side of the semiconductor substrate. A concentration distribution of the donors in the FS region include first, second, third and fourth peaks in order from a front surface to the rear surface. Each of the peaks has a peak maximum point, and peak end points formed at both sides of the peak maximum point. The peak maximum points of the first and second peaks are higher than the peak maximum point of the third peak. The peak maximum point of the third peak is lower than the peak maximum point of the fourth peak.

The present invention relates to a process for the production of structured, highly efficient solar cells and of photovoltaic elements which have regions of different doping. The invention likewise relates to the solar cells having increased efficiency produced in this way.

A method of manufacturing a semiconductor device having an insulated gate bipolar transistor portion and a freewheeling diode portion. The method includes introducing an impurity to a rear surface of a semiconductor substrate, performing first heat treating to activate the impurity to form a field stop layer, performing a first irradiation to irradiate light ions from the rear surface of semiconductor substrate to form, in the semiconductor substrate, a first low-lifetime region, performing a second irradiation to irradiate the light ions from the rear surface of the semiconductor substrate to form, in the field stop layer, a second low-lifetime region, and performing second heat treating to reduce a density of defects generated in the field stop layer when the second irradiation is performed. Each of the first and second low-lifetime regions has a carrier lifetime thereof shorter than that of any region of the semiconductor device other than the first and second low-lifetime regions.

A three-dimensional memory device includes a plurality of planes, each having a respective alternating stack, strings of memory stack structures which extends through the respective alternating stack, and backside contact via structures vertically extending through the respective alternating stack, extending generally along the first horizontal direction, and laterally separating neighboring pairs of strings of memory stack structures along a second horizontal direction. A first plane includes a first plurality of strings that are laterally spaced apart along the second horizontal direction by a first plurality of backside contact via structures. A second plane laterally shifted from the first plane along the first horizontal direction and including a second plurality of strings that are laterally spaced apart along the second horizontal direction by a second plurality of backside contact via structures which are laterally offset with respect the first plurality of backside contact via structures along the second horizontal direction.

A SiC MOSFET device having low specific on resistance is described. The device has N+, P-well and JFET regions extended in one direction (Y-direction) and P+ and source contacts extended in an orthogonal direction (X-direction). The polysilicon gate of the device covers the JFET region and is terminated over the P-well region to minimize electric field at the polysilicon gate edge. In use, current flows vertically from the drain contact at the bottom of the structure into the JFET region and then laterally in the X direction through the accumulation region and through the MOSFET channels into the adjacent N+ region. The current flowing out of the channel then flows along the N+ region in the Y-direction and is collected by the source contacts and the final metal. Methods of making the device are also described.

A SiC MOSFET device having low specific on resistance is described. The device has N+, P-well and JFET regions extended in one direction (Y-direction) and P+ and source contacts extended in an orthogonal direction (X-direction). The polysilicon gate of the device covers the JFET region and is terminated over the P-well region to minimize electric field at the polysilicon gate edge. In use, current flows vertically from the drain contact at the bottom of the structure into the JFET region and then laterally in the X direction through the accumulation region and through the MOSFET channels into the adjacent N+ region. The current flowing out of the channel then flows along the N+ region in the Y-direction and is collected by the source contacts and the final metal. Methods of making the device are also described.

According to one aspect thereof, there is provided a substrate processing apparatus including: a reaction tube including an outer tube and an inner tube; a manifold connected to an open end of the reaction tube; a lid configured to close one end of the manifold; a first gas supply pipe configured to supply a cleaning gas; and a second gas supply pipe configured to supply a purge gas of purging a space inside the manifold. The reaction tube includes: an exhaust space; an exhaust outlet communicating with the exhaust space; a first exhaust port provided in the inner tube so as to face a substrate accommodated in the inner tube; and second exhaust ports through which the exhaust space communicates with the space inside the manifold. At least one of the second exhaust ports promotes gas exhaust in the exhaust space distanced away from the first exhaust port.