Abstract: An exemplary method includes forming a common source region in a substrate, and forming an isolation feature over the common source region. The common source region is disposed between the substrate and the isolation feature. The common source region and the isolation feature span a plurality of active regions of the substrate. A gate, such as an erase gate, may be formed after forming the common source region. In some implementations, the common source region is formed by etching the substrate to form a saw-tooth shaped recess region (or a U-shaped recess region) and performing an ion implantation process to form a doped region in a portion of the saw-tooth shaped recess region (or the U-shaped recess region), such that the common source region has a sawtooth profile (or a U-shaped profile).

Abstract: The present disclosure involves forming a method of fabricating a Micro-Electro-Mechanical System (MEMS) device. A plurality of openings is formed in a first side of a first substrate. A dielectric layer is formed over the first side of the substrate. A plurality of segments of the dielectric layer fills the openings. The first side of the first substrate is bonded to a second substrate that contains a cavity. The bonding is performed such that the segments of the dielectric layer are disposed over the cavity. A portion of the first substrate disposed over the cavity is transformed into a plurality of movable components of a MEMS device. The movable components are in physical contact with the dielectric the layer. Thereafter, a portion of the dielectric layer is removed without using liquid chemicals.

Abstract: A microelectromechanical system (MEMS) structure and method of forming the MEMS device, including forming a first metallization structure over a complementary metal-oxide-semiconductor (CMOS) wafer, where the first metallization structure includes a first sacrificial oxide layer and a first metal contact pad. A second metallization structure is formed over a MEMS wafer, where the second metallization structure includes a second sacrificial oxide layer and a second metal contact pad. The first metallization structure and second metallization structure are then bonded together. After the first metallization structure and second metallization structure are bonded together, patterning and etching the MEMS wafer to form a MEMS element over the second sacrificial oxide layer. After the MEMS element is formed, removing the first sacrificial oxide layer and second sacrificial oxide layer to allow the MEMS element to move freely about an axis.

Abstract: A microelectromechanical system (MEMS) structure and method of forming the MEMS device, including forming a first metallization structure over a complementary metal-oxide-semiconductor (CMOS) wafer, where the first metallization structure includes a first sacrificial oxide layer and a first metal contact pad. A second metallization structure is formed over a MEMS wafer, where the second metallization structure includes a second sacrificial oxide layer and a second metal contact pad. The first metallization structure and second metallization structure are then bonded together. After the first metallization structure and second metallization structure are bonded together, patterning and etching the MEMS wafer to form a MEMS element over the second sacrificial oxide layer. After the MEMS element is formed, removing the first sacrificial oxide layer and second sacrificial oxide layer to allow the MEMS element to move freely about an axis.

Abstract: Some embodiments of the present disclosure relate to method of forming a memory device. In some embodiments, the method may be performed by forming a floating gate over a first dielectric on a substrate. A control gate is formed over the floating gate and first and second spacers are formed along sidewalls of the control gate. The first and second spacers extend past outer edges of an upper surface of the floating gate. An etching process is performed on the first and second spacers to remove a portion of the first and second spacers that extends past the outer edges of the upper surface of the floating gate along an interface between the first and second spacers and the floating gate.

Abstract: The present disclosure involves forming a method of fabricating a Micro-Electro-Mechanical System (MEMS) device. A plurality of openings is formed in a first side of a first substrate. A dielectric layer is formed over the first side of the substrate. A plurality of segments of the dielectric layer fills the openings. The first side of the first substrate is bonded to a second substrate that contains a cavity. The bonding is performed such that the segments of the dielectric layer are disposed over the cavity. A portion of the first substrate disposed over the cavity is transformed into a plurality of movable components of a MEMS device. The movable components are in physical contact with the dielectric the layer. Thereafter, a portion of the dielectric layer is removed without using liquid chemicals.

Abstract: A semiconductor structure for a split gate flash memory cell device with a hard mask having an asymmetric profile is provided. In some embodiments, a semiconductor substrate of the semiconductor structure includes a first source/drain region and a second source/drain region. A control gate and a memory gate, of the semiconductor structure, are spaced over the semiconductor substrate between the first and second source/drain regions. A charge trapping dielectric structure of the semiconductor structure is arranged between neighboring sidewalls of the memory gate and the control gate, and arranged under the memory gate. A hard mask of the semiconductor structure is arranged over the control gate and includes an asymmetric profile. The asymmetric profile tapers in height away from the memory gate. A method for manufacturing a pair of split gate flash memory cell devices with hard masks having an asymmetric profile is also provided.

Abstract: In some embodiments, a method for cleaning a processing chamber is provided. The method may be performed by introducing a processing gas into a processing chamber that has a by-product disposed along sidewalls of the processing chamber. A plasma is generated from the processing gas using a radio frequency signal. A lower electrode is connected to a first electric potential. Concurrently, a bias voltage having a second electric potential is applied to a sidewall electrode to induce ion bombardment of the by-product, in which the second electric potential has a larger magnitude than the first electric potential. The processing gas is evacuated from the processing chamber.

Abstract: A method for forming a pellicle apparatus involves forming a device substrate by depositing one or more pellicle layers defined over a base device layer, where a release layer is formed thereover. An adhesive layer is formed over a transparent carrier substrate. The adhesive layer is bonded to the release layer, defining a composite substrate comprised of the device and carrier substrates. The base device layer is removed from the composite structure and a pellicle frame is attached to an outermost one of the pellicle layers. A pellicle region is isolated from a remainder of the composite structure, and an ablation of the release layer is performed through the transparent carrier substrate, defining the pellicle apparatus comprising a pellicle film attached to the pellicle frame. The pellicle apparatus is then from a remaining portion of the composite substrate.

Abstract: A microelectromechanical system (MEMS) structure and method of forming the MEMS device, including forming a first metallization structure over a complementary metal-oxide-semiconductor (CMOS) wafer, where the first metallization structure includes a first sacrificial oxide layer and a first metal contact pad. A second metallization structure is formed over a MEMS wafer, where the second metallization structure includes a second sacrificial oxide layer and a second metal contact pad. The first metallization structure and second metallization structure are then bonded together. After the first metallization structure and second metallization structure are bonded together, patterning and etching the MEMS wafer to form a MEMS element over the second sacrificial oxide layer. After the MEMS element is formed, removing the first sacrificial oxide layer and second sacrificial oxide layer to allow the MEMS element to move freely about an axis.

Abstract: The present disclosure, in some embodiments, relates to a method of forming a memory cell. The method may be performed by forming a select gate on a side of a sacrificial spacer that is disposed over an upper surface of a substrate. The select gate has a non-planar top surface. An inter-gate dielectric layer is formed on the select gate and a memory gate is formed on the inter-gate dielectric layer. The inter-gate dielectric layer extends under the memory gate and defines a recess between sidewalls of the memory gate and select gate. The recess is filled with a first dielectric material.

Abstract: The present disclosure relates to a microelectromechanical systems (MEMS) package featuring a flat plate having a raised edge around its perimeter serving as an anti-stiction device, and an associated method of formation. A CMOS IC is provided having a dielectric structure surrounding a plurality of conductive interconnect layers disposed over a CMOS substrate. A MEMS IC is bonded to the dielectric structure such that it forms a cavity with a lowered central portion the dielectric structure, and the MEMS IC includes a movable mass that is arranged within the cavity. The CMOS IC includes an anti-stiction plate disposed under the movable mass. The anti-stiction plate is made of a conductive material and has a raised edge surrounding at least a part of a perimeter of a substantially planar upper surface.

Abstract: Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes a substrate having a first top surface, and an interconnection line over the first top surface of the substrate. The interconnection line has a sidewall. The semiconductor device structure also includes a first spacer over the sidewall of the interconnection line. The first spacer has a first concave surface which concaves towards the sidewall of the interconnection line. The semiconductor device structure further includes a dielectric layer covering the substrate, the interconnection line and the first spacer.

Abstract: A semiconductor structure and a method for forming the same are provided. The semiconductor structure includes a substrate, a gate structure over a first surface of the substrate, and a source region and a drain region in the substrate adjacent to the gate structure. The semiconductor structure further includes a channel region interposing the source and drain regions and underlying the gate structure. The semiconductor structure further includes a first layer over a second surface opposite to a first surface of the substrate, and a second layer over the first layer. The semiconductor structure further includes a sensing film over the channel region. The first opening and the second opening form a contiguous opening.

Abstract: The present disclosure relates to a split gate memory device. In some embodiments, the split gate memory device includes a memory gate arranged over a substrate, and a select gate arranged over the substrate. An inter-gate dielectric layer is arranged between sidewalls of the memory gate and the select gate that face one another. The inter-gate dielectric layer extends under the memory gate. A first dielectric is disposed above the inter-gate dielectric layer and is arranged between the sidewalls of the memory gate and the select gate.

Abstract: Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes a substrate having a first top surface, and an interconnection line over the first top surface of the substrate. The interconnection line has a sidewall. The semiconductor device structure also includes a first spacer over the sidewall of the interconnection line. The first spacer has a first concave surface which concaves towards the sidewall of the interconnection line. The semiconductor device structure further includes a dielectric layer covering the substrate, the interconnection line and the first spacer.

Abstract: A semiconductor structure and a method for forming the same are provided. The semiconductor structure comprises a substrate, a gate structure over a first surface of the substrate, and a source region and a drain region in the substrate adjacent to the gate structure. The semiconductor structure further comprises a channel region interposing the source and drain regions and underlying the gate structure. The semiconductor structure further comprises a first layer over a second surface of the substrate opposite to the first surface, and a second layer over the first layer. The semiconductor structure further comprises a sensing film over the channel region and at least a portion of the first and second layers, and a well over the sensing film and cutting off the first layer and the second layer.

Abstract: A method and apparatus for etching a wafer are provided. The method includes placing a first wafer with a first target material into a first chamber, and placing a second wafer with a second target material into a second chamber. The second chamber is connected to the first chamber by a first pipe. The method also includes applying a first Xe-containing gaseous etchant into the first chamber to etch the first target material. A portion of the first Xe-containing gaseous etchant in the first chamber is unreacted during the etching of the first target material. The method further includes applying the unreacted portion of the first Xe-containing gaseous etchant from the first chamber into the second chamber through the first pipe to etch the second target material of the second wafer.

Abstract: Structures and formation methods of a MEMS device structure are provided. The MEMS device structure includes a semiconductor substrate having a first region and a second region, and a MEMS layer over the semiconductor substrate. The MEMS layer has a first through hole positioned in the first region and a second through hole positioned in the second region. The MEMS device structure also includes a cap layer over the MEMS layer, a first cavity between the semiconductor substrate and the cap layer and in the first region, and a second cavity between the semiconductor substrate and the cap layer and in the second region. The MEMS device structure further includes a carbon-based degradation product in the first cavity.

Abstract: A method comprises forming a memory gate structure adjacent to a control gate structure over a substrate, wherein a charge storage layer is between the memory gate structure and the control gate structure and a top surface of the memory gate structure is covered by a gate mask layer, forming a first spacer along sidewalls of the memory gate structure and the gate mask layer, wherein a sidewall of the memory gate structure is fully covered by the first spacer, applying an etching process to the charge storage layer to form an L-shaped charge storage layer and forming a first drain/source region adjacent to the memory gate structure and a second drain/source region adjacent to the control gate structure.