Abstract: Provided are selector elements with active components comprising insulating matrices and mobile ions disposed within these insulating matrices. Also provided are methods of operating such selector elements. The insulating matrices and mobile ions may be formed from different combinations of materials. For example, the insulating matrix may comprise amorphous silicon or silicon oxide, while mobile ions may be silver ions. In another example, the active component comprises copper and germanium, selenium, or tellerium, e.g., Se61Cu39, Se67Cu33, or Se56Cu44. The active component may be a multilayered structure with a variable composition throughout the structure. For example, the concentration of mobile ions may be higher in a center of the structure, away from the electrode interfaces. In some embodiments, outer layers may be formed from Ge33Se24Cu47, while the middle layer may be formed from Ge47Se29Cu24.

Abstract: ALD of HfxAlyCz films using hafnium chloride (HfCl4) and Trimethylaluminum (TMA) precursors can be combined with post-deposition anneal processes and ALD liners to control the device characteristics in high-k metal-gate devices. Variation of the HfCl4 pulse time allows for control of the Al % incorporation in the HfxAlyCz film in the range of 10-13%. Combinatorial process tools can be employed for rapid electrical and materials characterization of various materials stacks. The effective work function (EWF) in metal oxide semiconductor capacitor (MOSCAP) devices with the HfxAlyCz work function layer coupled with ALD deposited HfO2 high-k gate dielectric layers was quantified to be mid-gap at ˜4.6 eV. Thus, HfxAlyCz is a promising metal gate work function material allowing for the tuning of device threshold voltages (Vth) for anticipated multi-Vth integrated circuit (IC) devices.

Abstract: Provided are selector elements having snapback characteristics and non-volatile memory cells comprising such selector elements. To achieve its snapback characteristic, a selector element may include a dielectric layer comprising an alloy of two or more materials. In the same or other embodiments, the selector element may include a doped electrode, such carbon electrodes doped with silicon, germanium, and/or selenium. Concentrations of different materials forming an alloy may vary throughout the thickness of the dielectric layer. For example, the concentration of the first one alloy material may be higher in the center of the dielectric layer than near the interfaces of the dielectric layer with the electrodes. Some examples of this alloy material include germanium, indium, and aluminum. Examples of other materials in the same alloy include silicon, gallium, arsenic, and antimony. In some embodiments, the alloy is formed by three or more elements, such as indium gallium arsenic.

Abstract: Embodiments provided herein describe systems and methods for forming semiconductor devices. A semiconductor substrate is provided. A source region and a drain region are formed on the semiconductor substrate. A gate electrode is formed between the source region and the drain region. A contact is formed above at least one of the source region and the drain region. The contact includes an insulating layer formed above the semiconductor substrate, an interface layer formed above the insulating layer, and a metallic layer formed above the interface layer. The interface layer is operable as a barrier between a material of the insulating layer and a material of the metallic layer, reduces the electrical resistance between the material of the insulating layer and the material of the metallic layer, or a combination thereof.

Abstract: An integrated circuit product includes an NMOS transistor having a gate structure that includes an NMOS gate insulation layer, a first NMOS metal layer positioned on the NMOS gate insulation layer, an NMOS metal silicide material positioned above the first NMOS metal layer, and a layer of a second metal material positioned above and in contact with the NMOS gate insulation layer, the first NMOS metal layer, and the NMOS metal silicide layer. The PMOS transistor has a gate structure that includes a PMOS gate insulation layer, a first PMOS metal layer positioned on the PMOS gate insulation layer, a PMOS metal silicide material positioned above the first PMOS metal layer, and a layer of the second metal material positioned above and in contact with the PMOS gate insulation layer, the first PMOS metal layer, and the PMOS metal silicide layer.

Abstract: ALD of HfxAlyCz films using hafnium chloride (HfCl4) and Trimethylaluminum (TMA) precursors can be combined with post-deposition anneal processes and ALD liners to control the device characteristics in high-k metal-gate devices. Variation of the HfCl4 pulse time allows for control of the Al % incorporation in the HfxAlyCz film in the range of 10-13%. Combinatorial process tools can be employed for rapid electrical and materials characterization of various materials stacks. The effective work function (EWF) in metal oxide semiconductor capacitor (MOSCAP) devices with the HfxAlyCz work function layer coupled with ALD deposited HfO2 high-k gate dielectric layers was quantified to be mid-gap at ˜4.6 eV. Thus, HfxAlyCz is a promising metal gate work function material allowing for the tuning of device threshold voltages (Vth) for anticipated multi-Vth integrated circuit (IC) devices.

Abstract: Metal-insulator-semiconductor (MIS) contacts for germanium and its alloys include insulator layers of oxygen-deficient metal oxide deposited by atomic layer deposition (ALD). The oxygen deficiency reduces the tunnel barrier resistance of the insulator layer while maintaining the layer's ability to prevent Fermi-level pinning at the metal/semiconductor interface. The oxygen deficiency is controlled by optimizing one or more ALD parameters such as shortened oxidant pulses, use of less-reactive oxidants such as water, heating the substrate during deposition, TMA “cleaning” of native oxide before deposition, and annealing after deposition. Secondary factors include reduced process-chamber pressure, cooled oxidant, and shortened pulses of the metal precursor.

Abstract: Methods and apparatus for processing using a remote plasma source are disclosed. The apparatus includes an outer chamber enclosing a substrate support, a remote plasma source, and a showerhead. A substrate heater can be mounted in the substrate support. A transport system moves the substrate support and is capable of positioning the substrate. The remote plasma source may be used to provide a plasma surface treatment or as a source to incorporate dopants into a pre-deposited layer.

Abstract: An integrated circuit product includes an NMOS transistor having a gate structure that includes an NMOS gate insulation layer, a first NMOS metal layer positioned on the NMOS gate insulation layer, an NMOS metal silicide material positioned above the first NMOS metal layer, and a layer of a second metal material positioned above and in contact with the NMOS gate insulation layer, the first NMOS metal layer, and the NMOS metal silicide layer. The PMOS transistor has a gate structure that includes a PMOS gate insulation layer, a first PMOS metal layer positioned on the PMOS gate insulation layer, a PMOS metal silicide material positioned above the first PMOS metal layer, and a layer of the second metal material positioned above and in contact with the PMOS gate insulation layer, the first PMOS metal layer, and the PMOS metal silicide layer.

Abstract: One method for forming replacement gate structures for NMOS and PMOS transistors includes performing an etching process to remove a sacrificial gate structure for the NMOS and PMOS transistors to thereby define NMOS and PMOS gate cavities, depositing a gate insulation layer in the gate cavities, depositing a first metal layer on the gate insulation layer in the gate cavities, performing at least one process operation to form (1) an NMOS metal silicide material above the first metal layer within the NMOS gate cavity, the NMOS metal silicide material having a first amount of atomic silicon, and (2) a PMOS metal silicide material above the first metal layer within the PMOS gate cavity, the PMOS metal silicide material having a second amount of atomic silicon, and wherein the first and second amounts of atomic silicon are different, and forming gate cap layers within the NMOS and PMOS gate cavities.

Abstract: Methods and apparatus for forming a dielectric layer for use as a gate dielectric are provided. A high-k layer is formed with first ALD process using a halogen-based precursor. The metal in the halogen-based precursor may be at least one of hafnium, zirconium, or titanium. The halogen in the halogen-based precursor may be at least one of fluorine, chlorine, or iodine. In some embodiments, the halogen-based metal precursor includes hafnium chloride. The remainder of the high-k layer is formed with second ALD process using a metal organic-based precursor. The metal in the metal organic-based precursor may be at least one of hafnium, zirconium, or titanium. The organic ligands in the metal organic-based precursor may be at least one of ?-diketonate precursors, alkoxide precursors, amino precursors. In some embodiments, the metal organic-based precursor includes amino precursors.

Abstract: Methods for fabricating integrated circuits are provided in various exemplary embodiments. In one embodiment, a method for fabricating an integrated circuit includes providing a germanium-based semiconductor substrate comprising a GeOx layer formed thereon having a first thickness, removing a portion of the GeOx layer by exposing the semiconductor substrate to a hydrogen-plasma dry etch so as to reduce the first thickness of the GeOx layer to a second thickness, and depositing a high-k material over the GeOx layer of the semiconductor substrate.

Abstract: Methods for fabricating integrated circuits are provided in various exemplary embodiments. In one embodiment, a method for fabricating an integrated circuit includes providing a germanium-based semiconductor substrate including a GeOx layer formed thereon having a first thickness, removing a portion of the GeOx layer by exposing the semiconductor substrate to a NF3/NH3 plasma dry etch so as to reduce the first thickness of the GeOx layer to a second thickness, and depositing a high-k material over the GeOx layer of the semiconductor substrate.

Abstract: Methods for fabricating integrated circuits are provided in various exemplary embodiments. In one embodiment, a method for fabricating an integrated circuit includes providing a germanium-based semiconductor substrate comprising a GeOx layer formed thereon and exposing the semiconductor substrate to first and second atomic layer deposition (ALD) processes. The first ALD process includes exposing the semiconductor substrate to a first gaseous precursor comprising aluminum and exposing the semiconductor substrate to a second gaseous precursor comprising a first oxygen-containing precursor. The second ALD process includes exposing the semiconductor substrate to a first gaseous precursor comprising aluminum and exposing the semiconductor substrate to a second gaseous precursor comprising a second oxygen-containing precursor.

Abstract: One method for forming replacement gate structures for NMOS and PMOS transistors includes performing an etching process to remove a sacrificial gate structure for the NMOS and PMOS transistors to thereby define NMOS and PMOS gate cavities, depositing a gate insulation layer in the gate cavities, depositing a first metal layer on the gate insulation layer in the gate cavities, performing at least one process operation to form (1) an NMOS metal silicide material above the first metal layer within the NMOS gate cavity, the NMOS metal silicide material having a first amount of atomic silicon, and (2) a PMOS metal silicide material above the first metal layer within the PMOS gate cavity, the PMOS metal silicide material having a second amount of atomic silicon, and wherein the first and second amounts of atomic silicon are different, and forming gate cap layers within the NMOS and PMOS gate cavities.

Abstract: Methods and apparatus for processing using a remote plasma source are disclosed. The apparatus includes an outer chamber enclosing a substrate support, a remote plasma source, and a showerhead. A substrate heater can be mounted in the substrate support. A transport system moves the substrate support and is capable of positioning the substrate. The remote plasma source may be used to provide a plasma surface treatment or as a source to incorporate dopants into a pre-deposited layer.

Abstract: A method includes forming an interlayer on a substrate, depositing a dielectric on the interlayer to form a dielectric stack, forming a sacrificial cap layer over the dielectric stack, processing the substrate to alter properties of the dielectric stack, and removing the sacrificial cap layer.

Abstract: Capacitor device structures can be fabricated on a substrate including multiple separate first electrodes and a common distributed second electrode. The second electrode can be common to the multiple first electrodes and can be distributed in a shape of a grid interdigitating the multiple first electrodes. The distributed nature of the second electrode can replace the substrate backside as the bottom electrode and can reduce the device parasitic characteristics. In some embodiments, the capacitor device structures can be used in a high productivity combinatorial process, wherein the distributed nature of the second electrode can make the test structures more tolerant to misalignment.