Abstract: An electrically programmable fuse comprising a cathode member, an anode member, and a link member, wherein the cathode member, the anode member, and the link member each comprise one of a plurality of materials operative to localize induced electromigration in the programmable fuse.

Abstract: A method for forming a memory device is provided by first forming at least one trench in a semiconductor substrate. Next, a lower electrode is formed in the at least one trench, and thereafter a conformal dielectric layer is formed on the lower electrode. An upper electrode is then formed on the conformal dielectric layer. The forming of the upper electrode may include a conformal deposition of metal nitride layer, and a non-conformal deposition of an electrically conductive material atop the metal nitride layer, in which the electrically conductive material encloses the at least one trench.

Abstract: A high tensile stress capping layer on Cu interconnects in order to reduce Cu transport and atomic voiding at the Cu/dielectric interface. The high tensile dielectric film is formed by depositing multiple layers of a thin dielectric material, each layer being under approximately 50 angstroms in thickness. Each dielectric layer is plasma treated prior to depositing each succeeding dielectric layer such that the dielectric cap has an internal tensile stress.

Abstract: A semiconductor device includes: a semiconductor substrate; a PFET formed on the substrate, the PFET includes a SiGe layer disposed on the substrate, a high-K dielectric layer disposed on the SiGe layer, a first metallic layer disposed on the high-k dielectric layer, a first intermediate layer disposed on the first metallic layer, a second metallic layer disposed on the first intermediate layer, a second intermediate layer disposed on the second metallic layer, and a third metallic layer disposed on the second intermediate layer; an NFET formed on the substrate, the NFET includes the high-k dielectric layer, the high-k dielectric layer being disposed on the substrate, the second intermediate layer, the second intermediate layer being disposed on the high-k dielectric layer, and the third metallic layer, the third metallic layer being disposed on the second intermediate layer. Alternatively, the first metallic layer is omitted.

Abstract: A metal gate and high-k dielectric device includes a substrate, an interfacial layer on top of the substrate, a high-k dielectric layer on top of the interfacial layer, a metal film on top of the high-k dielectric layer, a cap layer on top of the metal film and a metal gate layer on top of the cap layer. The thickness of the metal film and the thickness of the cap layer are tuned such that a target concentration of a cap layer material is present at an interface of the metal film and the high-k dielectric layer.

Abstract: A method and an apparatus are provided in which non-directional and directional metal (e.g. Ni) deposition steps are performed in the same process chamber. A first plasma is formed for removing material from a target; a secondary plasma for increasing ion density in the material is formed in the interior of an annular electrode (e.g. a Ni ring) connected to an RF generator. Material is deposited non-directionally on the substrate in the absence of the secondary plasma and electrical biasing of the substrate, and deposited directionally when the secondary plasma is present and the substrate is electrically biased. Nickel silicide formed from the deposited metal has a lower gate polysilicon sheet resistance and may have a lower density of pipe defects than NiSi formed from metal deposited in a solely directional process, and has a lower source/drain contact resistance than NiSi formed from metal deposited in a solely non-directional process.

Abstract: A metal gate and high-k dielectric device includes a substrate, an interfacial layer on top of the substrate, a high-k dielectric layer on top of the interfacial layer, a metal film on top of the high-k dielectric layer, a cap layer on top of the metal film and a metal gate layer on top of the cap layer. The thickness of the metal film and the thickness of the cap layer are tuned such that a target concentration of a cap layer material is present at an interface of the metal film and the high-k dielectric layer.

Abstract: A semiconductor structure and methods of making the same. The semiconductor structure includes a substrate having a silicide region disposed above a doped region, and a metal contact extending through the silicide region and being in direct contact with the doped region.

Abstract: Semiconductor structures, such as, for example, field effect transistors (FETs) and/or metal-oxide-semiconductor capacitor (MOSCAPs), are provided in which the workfunction of a conductive electrode stack is changed by introducing metal impurities into a metal-containing material layer which, together with a conductive electrode, is present in the electrode stack. The choice of metal impurities depends on whether the electrode is to have an n-type workfunction or a p-type workfunction. The present invention also provides a method of fabricating such semiconductor structures.

Abstract: Interconnect structures having improved electromigration resistance are provided that include a metallic interfacial layer (or metal alloy layer) that is present at the bottom of a via opening. The via opening is located within a second dielectric material that is located atop a first dielectric material that includes a first conductive material embedded therein. The metallic interfacial layer (or metal alloy layer) that is present at the bottom of the via opening is located between the underlying first conductive material embedded within the first dielectric and the second conductive material that is embedded within the second dielectric material. Methods of fabricating the improved electromigration resistance interconnect structures are also provided.

Abstract: A method of forming an interconnection in a semiconductor device includes forming a first liner in a dielectric layer therein; depositing a tungsten filler on top of the first liner; performing chemical mechanical planarization (CMP) to smooth out and remove the first liner and tungsten filler from the semiconductor's exposed surface; selectively removing the first liner and tungsten filler in the via; wherein the selective removing results in the first liner and the tungsten filler being removed in an upper region of the via; forming a second liner in the upper region of the via and tungsten filler; selectively removing the second liner from the tungsten filler; forming a copper seed layer on top of the tungsten filler; depositing a copper filler on top of the copper seed layer; and performing chemical CMP to smooth out and remove the second liner and copper filler from the semiconductor's exposed surface.

Abstract: Disclosed are embodiments of an improved high aspect ratio electroplated metal structure (e.g., a copper or copper alloy interconnect, such as a back end of the line (BEOL) or middle of the line (MOL) contact) in which the electroplated metal fill material is free from seams and/or voids. Also, disclosed are embodiments of a method of forming such an electroplated metal structure by lining a high aspect ratio opening (e.g., a high aspect ratio via or trench) with a metal-plating seed layer and, then, forming a protective layer over the portion of the metal-plating seed layer adjacent to the opening sidewalls so that subsequent electroplating occurs only from the bottom surface of the opening up.

Abstract: Disclosed are embodiments of an improved high aspect ratio electroplated metal structure (e.g., a copper or copper alloy interconnect, such as a back end of the line (BEOL) or middle of the line (MOL) contact) in which the electroplated metal fill material is free from seams and/or voids. Also, disclosed are embodiments of a method of forming such an electroplated metal structure by lining a high aspect ratio opening (e.g., a high aspect ratio via or trench) with a metal-plating seed layer and, then, forming a protective layer over the portion of the metal-plating seed layer adjacent to the opening sidewalls so that subsequent electroplating occurs only from the bottom surface of the opening up.

Abstract: A method of fabricating a MEMS switch having a free moving inductive element within in micro-cavity guided by at least one inductive coil. The switch consists of an upper inductive coil at one end of a micro-cavity; optionally, a lower inductive coil; and a free-moving inductive element preferably made of magnetic material. The coils are provided with an inner permalloy core. Switching is achieved by passing a current through the upper coil, inducing a magnetic field unto the inductive element. The magnetic field attracts the free-moving inductive element upwards, shorting two open conductive wires, closing the switch. When the current flow stops or is reversed, the free-moving magnetic element drops back by gravity to the bottom of the micro-cavity and the conductive wires open. When the chip is not mounted with the correct orientation, the lower coil pulls the free-moving inductive element back at its original position.

Abstract: A high tensile stress capping layer on Cu interconnects in order to reduce Cu transport and atomic voiding at the Cu/dielectric interface. The high tensile dielectric film is formed by depositing multiple layers of a thin dielectric material, each layer being under approximately 50 angstroms in thickness. Each dielectric layer is plasma treated prior to depositing each succeeding dielectric layer such that the dielectric cap has an internal tensile stress.

Abstract: Embodiments of the present invention provide a method of forming gate stacks for field-effect-transistors.

Abstract: A dielectric layer is patterned with at least one line trough and/or at least one via cavity. A metallic nitride liner is formed on the surfaces of the patterned dielectric layer. A metal liner is formed on the surface of the metallic nitride liner. A conformal copper nitride layer is formed directly on the metal liner by atomic layer deposition (ALD) or chemical vapor deposition (CVD). A Cu seed layer is formed directly on the conformal copper nitride layer. The at least one line trough and/or the at least one via cavity are filled with an electroplated material. The direct contact between the conformal copper nitride layer and the Cu seed layer provides enhanced adhesion strength. The conformal copper nitride layer may be annealed to covert an exposed outer portion into a contiguous Cu layer, which may be employed to reduce the thickness of the Cu seed layer.

Abstract: Disclosed is a structure and method for tuning silicide stress and, particularly, for developing a tensile silicide region on a gate conductor of an n-FET in order to optimize n-FET performance. More particularly, a first metal layer-protective cap layer-second metal layer stack is formed on an n-FET structure. However, prior to the deposition of the second metal layer, the protective layer is exposed to air. This air break step alters the adhesion between the protective cap layer and the second metal layer and thereby, effects the stress imparted upon the first metal layer during silicide formation. The result is a more tensile silicide that is optimal for n-FET performance.

Abstract: Forming a shallow trench capacitor in conjunction with an FET by forming a plurality of STI trenches; for the FET, implanting a first cell well having a first polarity between a first and a second of the STI trenches; for the capacitor, implanting a second cell well having a second polarity in an area of a third of the STI trenches; removing dielectric material from the third STI trench; forming a gate stack having a first portion located between the first and the second of the STI trenches and a second portion located over and extending into the third trench; and performing a source/drain implant of the same polarity as the second cell well, thereby forming a FET in the first cell well, and a capacitor in the second cell well. The second polarity may be opposite from the first polarity. An additional implant may reduce ESR in the second cell well.

Abstract: A PCM cell structure comprises a first electrode, a phase change element, and a second electrode, wherein the phase change element is inserted in between the first electrode and the second electrode and only the peripheral edge of the first electrode contacts the phase change element thereby reducing the contact area between the phase change element and the first electrode and thereby increasing the current density through the phase change element and effectively inducing the phase change at lower levels of current and reduced programming power.