Abstract: A method for making a composite integrated device includes providing a first integrated device having a substrate, an overlying interconnect region, and a contact, wherein the contact electrically contacts the interconnect region and is at a surface of the first integrated device. The method further includes forming a sidewall spacer along a sidewall of a first opening in a first dielectric layer, located over the surface of the integrated device, and providing a deformable metal feature adjacent to the sidewall spacer and in the first opening. The method further includes providing a second integrated device having a substrate, an overlying interconnect region, a contact, and a second dielectric layer surrounding the contact of the second integrated device. The method further includes contacting the contact of the second integrated device with the deformable metal feature and pressing the first dielectric layer against the second dielectric layer.

Abstract: A read only memory implemented as a 3D integrated device has a first stratum, a second stratum, and bonded inter-strata connections for coupling the first stratum to the second stratum. The physical bonding between the two strata implements the programming of the read only memory. The stratum may be in wafer form or in die form. The first stratum includes functional active devices and at least one non-programmed active device. The second stratum includes at least conductive routing to be associated with the at least one non-programmed active device. The bonded inter-strata connections include at least one bonded programmable inter-strata connection for programming the at least one non-programmed active device and for providing conductive routing to the programmed active device. The two strata thus form a programmed ROM. Other types of programmable storage devices may be implemented by bonding the two strata.

Abstract: A method for forming a conductive via is discussed and includes forming a seed layer over a first side of a semiconductor substrate, wherein the semiconductor substrate includes a first side opposite a second side, forming a via hole in a semiconductor substrate from the second side of the semiconductor substrate, wherein the via hole exposes the seed layer; and electroplating a conductive via material in the via hole from the seed layer. In one embodiment, a continuous conductive layer is formed over and electrically coupled to the seed layer. The continuous conductive layer can serve as the current source while electroplating the conductive via material.

Abstract: A semiconductor device is made by steps of removing portions of a first capping layer, removing portions of a sacrificial layer, recessing sidewalls, and forming fin structures. The step of removing portions of the first capping layer forms a first capping structure that covers portions of the sacrificial layer. The step of removing portions of the sacrificial layer removes portions of the sacrificial layer that are not covered by the first capping structure to define an intermediate structure. The step of recessing the sidewalls recesses sidewalls of the intermediate structure relative to edge regions of the first capping structure to form a sacrificial structure having recessed sidewalls. The step of forming fin structures forms fin structures adjacent to the recessed sidewalls.

Abstract: There is a method for forming a semiconductor device. Portions of a sacrificial layer are removed to expose a first seed layer region. The first seed layer region corresponds to a first semiconductor region, and a remaining portion of the sacrificial layer corresponds to a second semiconductor region. An epitaxial semiconductor material is deposited over the first seed layer region. A capping layer is formed to overlie the epitaxial semiconductor material and the remaining portion of the sacrificial layer. Portions of the capping layer are removed to form a capping structure that overlies a part of the remaining portion of the sacrificial layer. Portions of the sacrificial layer not covered by the capping structure are removed to form a sacrificial structure having sidewalls. Fin structures are formed adjoining the sidewalls by depositing a semiconductor material along the sidewalls. Portions of the capping structure are removed to expose portions of sacrificial layer between adjacent fin structures.

Abstract: To improve the mechanical strength of a wafer comprising a low-k dielectric layer, the low-k dielectric layer is formed so as to have certain regions of low dielectric constant and the remainder having a higher mechanical strength. The higher-strength regions may have a relatively-higher value of dielectric constant. Selective ultraviolet curing of a dielectric material can be performed so as to expel a porogen from the region(s) desired to have low dielectric constant. A photomask, hardmask, or opaque resist, patterned so as to define the region(s) to have lower dielectric constant, is used to shield the remainder of the dielectric material from the ultraviolet radiation. Alternatively, a layer of dielectric material can be blanket cured to lower its dielectric constant, then non-critical regions thereof can be selectively over-cured whereby to produce regions of increased mechanical strength.

Abstract: A reciprocal design symmetry allows stacked wafers or die on wafer to use identical designs or designs that vary only by a few layers (e.g. metal interconnect layers). Flipping or rotating one die or wafer allows the stacked die to have a reciprocal orientation with respect to each other which may be used to decrease the interconnect required between the vertically stacked die and or wafers. Flipping and/or rotating may also be used to improve heat dissipation when wafer and/or die are stacked. The stacked wafers or die may then be packaged.

Abstract: A wafer having an SOI configuration and active regions having different surface orientations for different channel type transistors. In one example, semiconductor structures having a first surface orientation are formed on a donor wafer. Semiconductor structures having a second surface orientation are formed on a second wafer. Receptor openings are formed on the second wafer. The semiconductor structures having the first surface orientation are located in the receptor openings and transferred to the second wafer. The resultant wafer has semiconductor regions having a first surface orientation for a first channel type of transistor and semiconductor regions having a second surface orientation for a second channel type transistor.

Abstract: An integration process where a first semiconductor protective layer and a second semiconductor protective layer are formed to protect the first and second semiconductor materials, respectfully, during processing to form an optical device, such as a photodetector, and a transistor on the same semiconductor. The first semiconductor protective layer protects the semiconductor substrate during formation of the second semiconductor layer, and the second semiconductor layer protects the second semiconductor material during subsequent processing of the first semiconductor. In one embodiment, the first semiconductor includes silicon and the second semiconductor material includes germanium.

Abstract: An automated method and system for identifying date-sensitive entries in a database wherein an obligation must be satisfied relative to the entry according to instructions provided by the beneficiary of the obligation. The method and system of the invention can be practiced from a location remote from the database and are particularly useful in a number of situations and particularly those wherein unticketed reservations are maintained in a storage medium for a time prior to issuance of a ticket to “firm up” the reservation to a ticketed status. The present system and methodology finds particular utility enforcing ticketing time limit rules on travel agency or other reservation and ticket issuers involved in the reserving and ticketing of airline bookings and the like and results in the reduction of no-shows and overbooking while increasing onboard load factors on sold-out flights in particular.

Abstract: A semiconductor fabrication process includes patterning a first gate electrode layer overlying a gate dielectric. A second gate electrode layer is formed overlying the first gate electrode layer and the gate dielectric. Portions of the second gate electrode layer overlying the first gate electrode layer are removed until the first and second gate electrode layers have the same thickness. A third gate electrode layer may be formed overlying the first and second gate electrode layers. The first gate electrode layer may comprise TiN and reside primarily overlying PMOS regions while the second gate electrode layer may comprise TaC or TaSiN and primarily overlie NMOS regions. Removing portions of the second gate electrode layer may include performing a chemical mechanical process (CMP) without masking the second gate electrode layer or forming a resist mask and etching exposed portions of the second gate electrode layer.

Abstract: One embodiment forms a gate dielectric layer over a substrate and then selectively deposits a first metal layer over portions of the gate dielectric layer in which a first device type will be formed. A second metal layer, different from the first metal layer, is formed over exposed portions of the gate dielectric layer in which a second device type will be formed. Each of the first and second device types will have different work functions because each will include a different metal in direct contact with the gate dielectric. In one embodiment, the selective deposition of the first metal layer is performed by ALD and with the use of an inhibitor layer which is selectively formed over the gate dielectric layer such that the first metal layer may be selectively deposited on only those portions of the gate dielectric layer which are not covered by the inhibitor layer.

Abstract: A self-aligned magnetic clad bit line structure (274) for a magnetic memory element (240a) and its method of formation are disclosed, wherein the self-aligned magnetic clad bit line structure (274) extends within a trench (258) and includes a conductive material (264), magnetic cladding sidewalls (262) and a magnetic cladding cap (252). The magnetic cladding sidewalls (262) at least partially surround the conductive material (264) and the magnetic cladding cap (252) is substantially recessed within the trench with respect to the top of the trench.

Abstract: A turbomachine frame member including an annular inner hub and a concentric annular outer casing that is spaced radially outwardly from the inner hub to define an annular flow passageway. A plurality of substantially radially-extending, circumferentially-spaced struts interconnect the inner hub and outer casing. The struts are connected to the outer casing by respective pairs of connecting bolts that pass through the outer casing and into the struts to engage barrel nuts.