Abstract: The present invention provides an interconnect structure that can be made in the BEOL which exhibits good mechanical contact during normal chip operations and does not fail during various reliability tests as compared with the conventional interconnect structures described above. The inventive interconnect structure has a kinked interface at the bottom of a via that is located within an interlayer dielectric layer. Specifically, the inventive interconnect structure includes a first dielectric layer having at least one metallic interconnect embedded within a surface thereof; a second dielectric layer located atop the first dielectric layer, wherein said second dielectric layer has at least one aperture having an upper line region and a lower via region, wherein the lower via region includes a kinked interface; at least one pair of liners located on at least vertical walls of the at least one aperture; and a conductive material filling the at least one aperture.

Abstract: A semiconductor device having wiring levels on opposite sides and a method of fabricating a semiconductor structure having contacts to devices and wiring levels on opposite sides. The method including fabricating a device on a silicon-on-insulator substrate with first contacts to the devices and wiring levels on a first side to the first contacts, removing a lower silicon layer to expose the buried oxide layer, forming second contacts to the devices through the buried oxide layer and forming wiring levels over the buried oxide layer to the second contacts.

Abstract: A design structure including design data describing a semiconductor structure. The semiconductor structure includes a first semiconductor chip and a second semiconductor chip. The first semiconductor chip is on top of and bonded to the second semiconductor chip. The first and second semiconductor chips include a first and a second electric nodes. The second semiconductor chip further includes a first comparing circuit. The semiconductor structure further includes a first coupling via electrically connecting the first electric node of the first semiconductor chip to the first comparing circuit of the second semiconductor chip. The first comparing circuit is capable of (i) receiving an input signal from the second electric node directly, (ii) receiving an input signal from the first electric node indirectly through the first coupling via, and (iii) asserting a first mismatch signal in response to the input signals from the first and second electric nodes being different.

Abstract: A method of forming damascene interconnect structure in an organo-silicate glass layer without causing damage to the organo-silicate glass material. The method includes forming a stack of hardmask layers over the organo-silicate glass layer, defining openings in the hardmask and organo-silicate glass layers using a combination of plasma etch and plasma photoresist removal processes and performing one or more additional plasma etch processes that do not include oxygen containing species to etch the openings to depths required for forming the damascene interconnect structures and to remove any organo-silicate material damaged by the combination of plasma etch and plasma photoresist removal processes.

Abstract: A semiconductor device having wiring levels on opposite sides and a method of fabricating a semiconductor structure having contacts to devices and wiring levels on opposite sides. The method including fabricating a device on a silicon-on-insulator substrate with first contacts to the devices and wiring levels on a first side to the first contacts, removing a lower silicon layer to expose the buried oxide layer, forming second contacts to the devices through the buried oxide layer and forming wiring levels over the buried oxide layer to the second contacts.

Abstract: A semiconductor device having wiring levels on opposite sides and a method of fabricating a semiconductor structure having contacts to devices and wiring levels on opposite sides. The method including fabricating a device on a silicon-on-insulator substrate with first contacts to the devices and wiring levels on a first side to the first contacts, removing a lower silicon layer to expose the buried oxide layer, forming second contacts to the devices through the buried oxide layer and forming wiring levels over the buried oxide layer to the second contacts.

Abstract: A method of making a diffusion barrier for a interconnect structure. The method comprises: providing a conductive line in a bottom dielectric trench; depositing a sacrificial liner on the cap layer; depositing an interlayer dielectric; forming a trench and a via in the top interlayer dielectric; and removing a portion of the cap layer and the sacrificial layer proximate to the bottom surface of the via. The removed portions of the cap layer and sacrificial layer deposit predominantly along the lower sidewalls of the via. The conductive line is in contact with a cap layer, and the sacrificial layer is in contact with the cap layer. The invention is also directed to the interconnect structures resulting from the inventive process.

Abstract: A method of forming damascene interconnect structure in an organo-silicate glass layer without causing damage to the organo-silicate glass material. The method includes forming a stack of hardmask layers over the organo-silicate glass layer, defining openings in the hardmask and organo-silicate glass layers using a combination of plasma etch and plasma photoresist removal processes and performing one or more additional plasma etch processes that do not include oxygen containing species to etch the openings to depths required for forming the damascene interconnect structures and to remove any organo-silicate material damaged by the combination of plasma etch and plasma photoresist removal processes.

Abstract: A method for making dual pre-doped gate stacks used in semiconductor applications such as complementary metal oxide semiconductor (CMOS) devices and metal oxide semiconductor field effect transistors (MOSFETs) is provided. The method involves providing at least one pre-doped conductive layer, such as poly silicon (poly-Si), on a gate stack and etching by exposing the conductive layer to an etching composition comprising at least one carbon containing gas. The carbon containing gas can be selected from gases having the general formula CxHy, such as, for example, CH4, C2H2, C2H4, and C2H6. The carbon containing gas can further be selected from gases having the general formula CxHyA, wherein A can represent one or more additional substituents selected from O, N, P, S, F, Cl, Br, and I. The processes can result in dual pre-doped gate stacks having essentially vertical sidewalls and further having a width of at least about 3 nm, such as from about 5 nm to about 150 nm.

Abstract: Methods are provided for fabricating semiconductor IC (integrated circuit) chips having high-Q on-chip inductors formed on the chip backside and connected to integrated circuits on the chip frontside using through-wafer interconnects. For example, a semiconductor device with a backside integrated inductor includes a semiconductor substrate having a frontside, a backside and a buried insulating layer interposed between the front and backsides of the substrate. An integrated circuit is formed on the frontside of the semiconductor substrate and an integrated inductor is formed on the backside of the semiconductor substrate. An interconnection structure is formed through the buried insulating layer to connect the integrated inductor to the integrated circuit. The semiconductor substrate may be an SOI (silicon on insulator) structure.

Abstract: Methods are provided for fabricating semiconductor IC (integrated circuit) chips having high-Q on-chip capacitors formed on the chip back-side and connected to integrated circuits on the chip front-side using through-wafer interconnects. In one aspect, a semiconductor device includes a semiconductor substrate having a front side, a back side, and a buried insulating layer interposed between the front and back sides of the substrate. An integrated circuit is formed on the front side of the semiconductor substrate, an integrated capacitor is formed on the back side of the semiconductor substrate, and an interconnection structure is formed through the buried insulating layer to connect the integrated capacitor to the integrated circuit.

Abstract: A semiconductor structure and method of fabricating the structure. The method includes removing the backside silicon from two silicon-on-insulator wafers having devices fabricated therein and bonding them back to back utilizing the buried oxide layers. Contacts are then formed in the upper wafer to devices in the lower wafer and wiring levels are formed on the upper wafer. The lower wafer may include wiring levels. The lower wafer may include landing pads for the contacts. Contacts to the silicon layer of the lower wafer may be silicided.

Abstract: A semiconductor device having wiring levels on opposite sides and a method of fabricating a semiconductor structure having contacts to devices and wiring levels on opposite sides. The method including fabricating a device on a silicon-on-insulator substrate with first contacts to the devices and wiring levels on a first side to the first contacts, removing a lower silicon layer to expose the buried oxide layer, forming second contacts to the devices through the buried oxide layer and forming wiring levels over the buried oxide layer to the second contacts.

Abstract: The present invention provides an interconnect structure that can be made in the BEOL which exhibits good mechanical contact during normal chip operations and does not fail during various reliability tests as compared with the conventional interconnect structures described above. The inventive interconnect structure has a kinked interface at the bottom of a via that is located within an interlayer dielectric layer. Specifically, the inventive interconnect structure includes a first dielectric layer having at least one metallic interconnect embedded within a surface thereof; a second dielectric layer located atop the first dielectric layer, wherein said second dielectric layer has at least one aperture having an upper line region and a lower via region, wherein the lower via region includes a kinked interface; at least one pair of liners located on at least vertical walls of the at least one aperture; and a conductive material filling the at least one aperture.

Abstract: A novel asymmetric filter membrane, and process for making is disclosed in several exemplary versions. The membrane structure is physically robust and suitable for use in a wide variety of applications. The support membrane is may be comprised of material such as a porous silicon or a silicon oxide, and the separation membrane may be comprised of material such as a polymer, zeolite film, or silicon oxide. The process relies on steps adapted from the microelectronics industry.

Abstract: Disclosed is a method for depositing a metal layer on an interconnect structure for a semiconductor wafer. In the method, a metal conductor is covered by a capping layer and a dielectric layer. The dielectric layer is patterned so as to expose the capping layer. The capping layer is then sputter etched to remove the capping layer and expose the metal conductor. In the process of sputter etching, the capping layer is redeposited onto the sidewall of the pattern. Lastly, at least one layer is deposited into the pattern and covers the redeposited capping layer.

Abstract: Structures for aligning wafers and methods for operating the same. The structure includes (a) a first semiconductor wafer including a first capacitive coupling structure, and (b) a second semiconductor wafer including a second capacitive coupling structure. The first and second semiconductor wafers are in direct physical contact with each other via a common surface. If the first and second semiconductor wafers are moved with respect to each other by a first displacement distance of 1 nm in a first direction while the first and second semiconductor wafers are in direct physical contact with each other via the common surface, then a change of at least 10?18 F in capacitance of a first capacitor comprising the first and second capacitive coupling structures results. The first direction is essentially parallel to the common surface.

Abstract: Gate conductors on an integrated circuit are formed with enlarged upper portions which are utilized to electrically connect the gate conductors with other devices. A semiconductor device comprises a gate conductor with an enlarged upper portion which electrically connects the gate conductor to a local diffusion region. Another semiconductor device comprises two gate conductors with enlarged upper portions which merge to create electrically interconnected gate conductors. Methods for forming the above semiconductor devices are also described and claimed.

Abstract: A novel air-gap-containing interconnect wiring structure is described incorporating a solid low-k dielectric in the via levels, and a composite solid plus air-gap dielectric in the wiring levels. Also provided is a method for forming such an interconnect structure. The method is readily scalable to interconnect structures containing multiple wiring levels, and is compatible with Dual Damascene Back End of the Line (BEOL) processing.

Abstract: In a multilevel microelectronic integrated circuit, air comprises permanent line level dielectric and ultra low-K materials are via level dielectric. The air is supplied to line level subsequent to removal of sacrificial material by clean thermal decomposition and assisted diffusion of byproducts through porosities in the IC structure. Optionally, air is also included within porosities in the via level dielectric. By incorporating air to the extent produced in the invention, intralevel and interlevel dielectric values are minimized.