Abstract: Forming a first sidewall spacer adjacent a vertically oriented channel semiconductor structure (“VCS structure’) and adjacent a cap layer, performing at least one planarization process so as to planarize an insulating material and expose an upper surface of the cap layer and an upper surface of the first spacer and removing a portion of the first spacer and an entirety of the cap layer so as to thereby expose an upper surface of the VCS structure and define a spacer/contact cavity above the VCS structure and the first spacer. The method also includes forming a second spacer in the spacer/contact cavity, forming a top source/drain region in the VCS structure and forming a top source/drain contact within the spacer/contact cavity that is conductively coupled to the top source/drain region, wherein the conductive contact physically contacts the second spacer in the spacer/contact cavity.

Abstract: Disclosed are semiconductor structures and methods of forming them. The structures include field effect transistors (FETs) with different type conductivities in different levels, respectively, of the same fin, wherein the numbers of FETs in the different levels are different. Specifically, in a fin, a first semiconductor layer has source/drain and channel regions for a first and a second transistor and a second semiconductor layer has source/drain and channel regions for a third transistor with a different type conductivity than first and second transistors. A gate is on the top surface and sides of the first semiconductor layer at the channel region of the first transistor. Another gate has a lower portion on the sides of the first semiconductor layer at the channel region of the second transistor and an upper portion on the top surface and sides of the second semiconductor layer at the channel region of the third transistor.

Abstract: A sequence of semiconductor processing steps permits formation of both vertical and horizontal nanometer-scale serpentine resistors and parallel plate capacitors within a common structure. The method takes advantage of a CMP process non-uniformity in which the CMP polish rate of an insulating material varies according to a certain underlying topography. By establishing such topography underneath a layer of the insulating material, different film thicknesses of the insulator can be created in different areas by leveraging differential polish rates, thereby avoiding the use of a lithography mask. In one embodiment, a plurality of resistors and capacitors can be formed as a compact integrated structure within a common dielectric block, using a process that requires only two mask layers. The resistors and capacitors thus formed as a set of integrated circuit elements are suitable for use as microelectronic fuses and antifuses, respectively, to protect underlying microelectronic circuits.

Abstract: A wavy line interconnect structure that accommodates small metal lines and enlarged diameter vias is disclosed. The enlarged diameter vias can be formed using a self-aligned dual damascene process without the need for a separate via lithography mask. The enlarged diameter vias make direct contact with at least three sides of the underlying metal lines, and can be aligned asymmetrically with respect to the metal line to increase the packing density of the metal pattern. The resulting vias have an aspect ratio that is relatively easy to fill, while the larger via footprint provides low via resistance. An interconnect structure having enlarged diameter vias can also feature air gaps to reduce the chance of dielectric breakdown. By allowing the via footprint to exceed the minimum size of the metal line width, a path is cleared for further process generations to continue shrinking metal lines to dimensions below 10 nm.

Abstract: Embodiments of the present invention provide methods and structures by which the inherent discretization of effective width can be relaxed through introduction of a fractional effective device width, thereby allowing greater flexibility for design applications, such as SRAM design optimization. A portion of some fins are clad with a capping layer or workfunction material to change the threshold voltage (Vt) for a part of the fin, rendering that part of the fin electrically inactive, which changes the effective device width (Weff). Other fins are unclad, and provide maximum area of constant threshold voltage. In this way, the effective device width of some devices is reduced. Therefore, the effective device width is controllable by controlling the level of cladding of the fin.

Abstract: Various embodiments facilitate die protection for an integrated circuit. In one embodiment, a multilayer structure is formed in multiple levels and along the edges of a die to prevent and detect damages to the die. The multilayer structure includes a support layer, a first plurality of dielectric pillars overlying the support layer, a metal layer that fills spaces between the first plurality of dielectric pillars, an insulation layer overlying the first plurality of dielectric pillars and the metal layer, a second plurality of dielectric pillars overlying the insulation layer, and a second metal layer that fills spaces between the second plurality of dielectric pillars.

Abstract: A wavy line interconnect structure that accommodates small metal lines and enlarged diameter vias is disclosed. The enlarged diameter vias can be formed using a self-aligned dual damascene process without the need for a separate via lithography mask. The enlarged diameter vias make direct contact with at least three sides of the underlying metal lines, and can be aligned asymmetrically with respect to the metal line to increase the packing density of the metal pattern. The resulting vias have an aspect ratio that is relatively easy to fill, while the larger via footprint provides low via resistance. An interconnect structure having enlarged diameter vias can also feature air gaps to reduce the chance of dielectric breakdown. By allowing the via footprint to exceed the minimum size of the metal line width, a path is cleared for further process generations to continue shrinking metal lines to dimensions below 10 nm.

Abstract: A sequence of semiconductor processing steps permits formation of both vertical and horizontal nanometer-scale serpentine resistors and parallel plate capacitors within a common structure. The method of fabricating such a structure cleverly takes advantage of a CMP process non-uniformity in which the CMP polish rate of an insulating material varies according to a certain underlying topography. By establishing such topography underneath a layer of the insulating material, different film thicknesses of the insulator can be created in different areas by leveraging differential polish rates, thereby avoiding the use of a lithography mask. In one embodiment, a plurality of resistors and capacitors can be formed as a compact integrated structure within a common dielectric block, using a process that requires only two mask layers.

Abstract: Vertical GAA FET structures are disclosed in which a current-carrying nanowire is oriented substantially perpendicular to the surface of a silicon substrate. The vertical GAA FET is intended to meet design and performance criteria for the 7 nm technology generation. In some embodiments, electrical contacts to the drain and gate terminals of the vertically oriented GAA FET can be made via the backside of the substrate. Examples are disclosed in which various n-type and p-type transistor designs have different contact configurations. In one example, a backside gate contact extends through the isolation region between adjacent devices. Other embodiments feature dual gate contacts for circuit design flexibility. The different contact configurations can be used to adjust metal pattern density.

Abstract: Various embodiments facilitate die protection for an integrated circuit. In one embodiment, a multilayer structure is formed in multiple levels and along the edges of a die to prevent and detect damages to the die. The multilayer structure includes a support layer, a first plurality of dielectric pillars overlying the support layer, a metal layer that fills spaces between the first plurality of dielectric pillars, an insulation layer overlying the first plurality of dielectric pillars and the metal layer, a second plurality of dielectric pillars overlying the insulation layer, and a second metal layer that fills spaces between the second plurality of dielectric pillars.

Abstract: Nanoscale efuses, antifuses, and planar coil inductors are disclosed. A copper damascene process can be used to make all of these circuit elements. A low-temperature copper etch process can be used to make the efuses and efuse-like inductors. The circuit elements can be designed and constructed in a modular fashion by linking a matrix of metal columns in different configurations and sizes. The number of metal columns, or the size of a dielectric mesh included in the circuit element, determines its electrical characteristics. Alternatively, the efuses and inductors can be formed from interstitial metal that is either deposited into a matrix of dielectric columns, or left behind after etching columnar openings in a block of metal. Arrays of metal columns also serve a second function as features that can improve polish uniformity in place of conventional dummy structures. Use of such modular arrays provides flexibility to integrated circuit designers.

Abstract: Nanoscale efuses, antifuses, and planar coil inductors are disclosed. A copper damascene process can be used to make all of these circuit elements. A low-temperature copper etch process can be used to make the efuses and efuse-like inductors. The circuit elements can be designed and constructed in a modular fashion by linking a matrix of metal columns in different configurations and sizes. The number of metal columns, or the size of a dielectric mesh included in the circuit element, determines its electrical characteristics. Alternatively, the efuses and inductors can be formed from interstitial metal that is either deposited into a matrix of dielectric columns, or left behind after etching columnar openings in a block of metal. Arrays of metal columns also serve a second function as features that can improve polish uniformity in place of conventional dummy structures. Use of such modular arrays provides flexibility to integrated circuit designers.

Abstract: Ultra-low-k dielectric materials used as inter-layer dielectrics in high-performance integrated circuits are prone to be structurally unstable. The Young's modulus of such materials is decreased, resulting in porosity, poor film strength, cracking, and voids. An alternative dual damascene interconnect structure incorporates deep air gaps into a high modulus dielectric material to maintain structural stability while reducing capacitance between adjacent nanowires. Incorporation of a deep air gap having k=1.0 compensates for the use of a higher modulus film having a dielectric constant greater than the typical ultra-low-k (ULK) dielectric value of about 2.2. The higher modulus film containing the deep air gap is used as an insulator and a means of reducing fringe capacitance between adjacent metal lines. The dielectric layer between two adjacent metal lines thus forms a ULK/high-modulus dielectric bi-layer.

Abstract: An integrated circuit includes a substrate with an interlevel dielectric layer positioned above the substrate. First trenches having a first depth are formed in the interlevel dielectric layer and a metal material fills the first trenches to form first interconnection lines. Second trenches having a second depth are also formed in the interlevel dielectric layer and filled with a metal material to form second interconnection lines. The first and second interconnection lines have a substantially equal pitch, which in a preferred implementation is a sub-lithographic pitch, and different resistivities due to the difference in trench depth. The first and second trenches are formed with an etching process through a hard mask having corresponding first and second openings of different depths. A sidewall image transfer process is used to define sub-lithographic structures for forming the first and second openings in the hard mask.

Abstract: A wavy line interconnect structure that accommodates small metal lines and large vias is disclosed. A lithography mask design used to pattern metal line trenches uses optical proximity correction (OPC) techniques to approximate wavy lines using rectangular opaque features. The large vias can be formed using a self-aligned dual damascene process without the need for a separate via lithography mask. Instead, a sacrificial layer allows etching of an underlying thick dielectric block, while protecting narrow features of the trenches that correspond to the metal line interconnects. The resulting vias have an aspect ratio that is relatively easy to fill, while the larger via footprint provides low via resistance. By lifting the shrink constraint for vias, thereby allowing the via footprint to exceed the minimum size of the metal line width, a path is cleared for further process generations to continue shrinking metal lines to dimensions below 10 nm.

Abstract: A wavy line interconnect structure that accommodates small metal lines and enlarged diameter vias is disclosed. The enlarged diameter vias can be formed using a self-aligned dual damascene process without the need for a separate via lithography mask. The enlarged diameter vias make direct contact with at least three sides of the underlying metal lines, and can be aligned asymmetrically with respect to the metal line to increase the packing density of the metal pattern. The resulting vias have an aspect ratio that is relatively easy to fill, while the larger via footprint provides low via resistance. An interconnect structure having enlarged diameter vias can also feature air gaps to reduce the chance of dielectric breakdown. By allowing the via footprint to exceed the minimum size of the metal line width, a path is cleared for further process generations to continue shrinking metal lines to dimensions below 10 nm.

Abstract: Ultra-low-k dielectric materials used as inter-layer dielectrics in high-performance integrated circuits are prone to be structurally unstable. The Young's modulus of such materials is decreased, resulting in porosity, poor film strength, cracking, and voids. An alternative dual damascene interconnect structure incorporates air gaps into a high modulus dielectric material to maintain structural stability while reducing capacitance between adjacent nanowires. Incorporation of an air gap having k=1.0 compensates for the use of a higher modulus film having a dielectric constant greater than the typical ultra-low-k (ULK) dielectric value of about 2.2. The higher modulus film containing the air gap is used as an insulator between adjacent metal lines, while a ULK film is retained to insulate vias. The dielectric layer between two adjacent metal lines thus forms a ULK/high-modulus dielectric bi-layer.

Abstract: Ultra-low-k dielectric materials used as inter-layer dielectrics in high-performance integrated circuits are prone to be structurally unstable. The Young's modulus of such materials is decreased, resulting in porosity, poor film strength, cracking, and voids. An alternative dual damascene interconnect structure incorporates deep air gaps into a high modulus dielectric material to maintain structural stability while reducing capacitance between adjacent nanowires. Incorporation of a deep air gap having k=1.0 compensates for the use of a higher modulus film having a dielectric constant greater than the typical ultra-low-k (ULK) dielectric value of about 2.2. The higher modulus film containing the deep air gap is used as an insulator and a means of reducing fringe capacitance between adjacent metal lines. The dielectric layer between two adjacent metal lines thus forms a ULK/high-modulus dielectric bi-layer.

Abstract: A sequence of semiconductor processing steps permits formation of both vertical and horizontal nanometer-scale serpentine resistors and parallel plate capacitors within a common structure. The method of fabricating such a structure cleverly takes advantage of a CMP process non-uniformity in which the CMP polish rate of an insulating material varies according to a certain underlying topography. By establishing such topography underneath a layer of the insulating material, different film thicknesses of the insulator can be created in different areas by leveraging differential polish rates, thereby avoiding the use of a lithography mask. In one embodiment, a plurality of resistors and capacitors can be formed as a compact integrated structure within a common dielectric block, using a process that requires only two mask layers.

Abstract: A plurality of metal tracks are formed in an integrated circuit die in three metal layers stacked within the die. A protective dielectric layer is formed around metal tracks of an intermediate metal layer. The protective dielectric layer acts as a hard mask to define contact vias between metal tracks in the metal layers above and below the intermediate metal layer.