A semiconductor on insulator type structure, which may be used for a front side type imager, successively comprises, from its rear side to its front side, a semiconductor support substrate, an electrically insulating layer and an active layer comprising a monocrystalline semiconductor material. The active layer is made of a semiconductor material having a state of mechanical stress with respect to the support substrate, and the support substrate comprises, on its rear side, a silicon oxide layer, the thickness of the oxide layer being chosen to compensate bow induced by the mechanical stress between the active layer and the support substrate during cooling of the structure after the formation by epitaxy of at least a part of the active layer on the support substrate.

A metal plate to be used in the manufacture of a deposition mask comprises: a base metal plate; and a surface layer disposed on the base metal plate, wherein the surface layer includes elements different from those of the base metal plate, or has a composition ratio different from that of the base metal plate, and an etching rate of the base metal plate is greater than the etching rate of the surface layer. An embodiment includes a manufacturing method for a deposition mask having an etching factor greater than or equal to 2.5. The deposition mask of the embodiment includes a deposition pattern region and a non-deposition region, the deposition pattern region includes a plurality of through-holes, the deposition pattern region is divided into an effective region, a peripheral region, and a non-effective region, and through-holes can be formed in the effective region and the peripheral region.

An end effector for moving workpieces and replaceable parts within a system for processing workpieces. The end effector may include an arm portion extending between a first arm end and a second arm end along the axial direction. The end effector may further include a spatula portion extending between a first spatula end and a second spatula end, the first spatula end being adjacent the second arm end. Further, the end effector may include a first support member extending outwardly from the spatula portion, a second support member extending outwardly from the spatula portion, and a shared support member extending outwardly from the arm portion. The shared support member and the first support member together to support workpieces of a first diameter, and the shared support member and the second support member together support replaceable parts of a second diameter.

A semiconductor device having a planar III-N semiconductor layer, comprising a substrate comprising a wafer (101) and a buffer layer (102), of a buffer material different from a material of the wafer, the buffer layer having a growth surface (1021); an array of nano structures (1010) epitaxially grown from the growth surface; a continuous planar layer (1020) formed by coalescence of upper parts of the nano structures at an elevated temperature T, wherein the number of lattice cells spanning a center distance between adjacent nano structures are different at the growth surface and at the coalesced planar layer; a growth layer (1030), epitaxially grown on the planar layer (1020).

A method of forming a semiconductor device including a fin field effect transistor (FinFET), the method includes forming a first sacrificial layer over a source/drain structure of a FinFET structure and an isolation insulating layer. The first sacrificial layer is patterned, thereby forming an opening. A first liner layer is formed on the isolation insulating layer in a bottom of the opening and on at least side faces of the patterned first sacrificial layer. After the first liner layer is formed, forming a dielectric layer in the opening. After the dielectric layer is formed, removing the patterned first sacrificial layer, thereby forming a contact opening over the source/drain structure. A conductive layer is formed in the contact opening. The FinFET is an n-type FET, and the source/drain structure includes an epitaxial layer made of Si.sub.1-y-a-bGe.sub.aSn.sub.bM2.sub.y, wherein 0<a, 0<b, 0.01≤(a+b)≤0.1, 0.01≤y≤0.1, and M2 is P or As.

A sputtering device includes a processing chamber where a substrate is accommodated, and a slit plate that partitions the processing chamber into a first space where a target member is disposed and a second space where the substrate is disposed. The slit plate includes an inner member having an opening that penetrates therethrough in a thickness direction of the slit plate, and an outer member disposed around the inner member. The inner member is attachable to and detachable from the outer member.

A sputtering method including: performing a pre-sputtering by emitting sputter particles from a target provided in a sputtering apparatus in a state where the target is shielded by a shielding portion of a shutter provided closed to the target to be capable of opening/closing the target; and, after the pre-sputtering, performing a main-sputtering by emitting the sputter particles from the target in a state where an opening of the shutter is aligned with the target thereby depositing the sputter particles on a substrate. When the pre-sputtering and the main-sputtering are repeatedly performed, a shutter position is changed during the pre-sputtering so as to change a position of the shielding portion aligned with the target.

Disclosed herein are methods for forming split-gate MOSFETs including a gate shield. In some embodiments, a method may include providing a device structure including a well formed in an epitaxial layer, forming a set of trenches through the well and the epitaxial layer, implanting the device structure to form a gate shield layer at a bottom of each of the set of trenches, and forming a gate spacer layer over the device structure including within the set of trenches.

A metal plate to be used in the manufacture of a deposition mask comprises: a base metal plate; and a surface layer disposed on the base metal plate, wherein the surface layer includes elements different from those of the base metal plate, or has a composition ratio different from that of the base metal plate, and an etching rate of the base metal plate is greater than the etching rate of the surface layer. An embodiment includes a manufacturing method for a deposition mask having an etching factor greater than or equal to 2.5. The deposition mask of the embodiment includes a deposition pattern region and a non-deposition region, the deposition pattern region includes a plurality of through-holes, the deposition pattern region is divided into an effective region, a peripheral region, and a non-effective region, and through-holes can be formed in the effective region and the peripheral region.

A metal plate to be used in the manufacture of a deposition mask comprises: a base metal plate; and a surface layer disposed on the base metal plate, wherein the surface layer includes elements different from those of the base metal plate, or has a composition ratio different from that of the base metal plate, and an etching rate of the base metal plate is greater than the etching rate of the surface layer. An embodiment includes a manufacturing method for a deposition mask having an etching factor greater than or equal to 2.5. The deposition mask of the embodiment includes a deposition pattern region and a non-deposition region, the deposition pattern region includes a plurality of through-holes, the deposition pattern region is divided into an effective region, a peripheral region, and a non-effective region, and through-holes can be formed in the effective region and the peripheral region.