Abstract: In some embodiments, a semiconductor surface having a high mobility semiconductor may be effectively passivated by nitridation, preferably using hydrazine, a hydrazine derivative, or a combination thereof. The surface may be the semiconductor surface of a transistor channel region. In some embodiments, a semiconductor surface oxide layer is formed at the semiconductor surface and the passivation is accomplished by forming a semiconductor oxynitride layer at the surface, with the nitridation contributing nitrogen to the surface oxide to form the oxynitride layer. The semiconductor oxide layer may be deposited by atomic layer deposition (ALD) and the nitridation may also be conducted as part of the ALD.

Abstract: In some embodiments, an MIS-type contact structure is formed by passivating the semiconductor surface of a source/drain region with a chalcogen, and subsequently depositing an tunnel layer by first exposing the chalcogen-passivated surface to a metal-organic precursor. Subsequently, deposition of the tunnel layer continues to a desired thickness. Preferably, the metal-organic precursor is part of a first set of ALD precursors and a second set of ALD precursors, which include one or more metal or semimetal precursors, are subsequently used to continue the deposition. For example, the metal-organic precursor may be used to deposit a first portion of the tunnel layer, and an inorganic metal or inorganic semimetal precursor or a different organic metal or organic semimetal precursor may be used to deposit a second portion of the tunnel layer. A metal is subsequently deposited on the tunnel layer, e.g., to form a metal electrode or electrical contact.

Abstract: A method for forming a resistive random access memory (RRAM) device is disclosed. The method comprises forming a first electrode, forming a resistive switching oxide layer comprising a metal oxide by thermal atomic layer deposition (ALD), doping the resistive switching oxide layer with a metal dopant different from metal forming the metal oxide, and forming a second electrode by thermal atomic layer deposition (ALD), where the resistive switching layer is interposed between the first electrode and the second electrode. In some embodiments, forming the resistive switching oxide may be performed without exposing a surface of the switching oxide layer to a surface-modifying plasma treatment after depositing the metal oxide.

Abstract: A process for depositing titanium aluminum or tantalum aluminum thin films comprising nitrogen on a substrate in a reaction space can include at least one deposition cycle. The deposition cycle can include alternately and sequentially contacting the substrate with a vapor phase Ti or Ta precursor and a vapor phase Al precursor. At least one of the vapor phase Ti or Ta precursor and the vapor phase Al precursor may contact the substrate in the presence of a vapor phase nitrogen precursor.

Abstract: Embodiments related to methods for forming a film stack on a substrate are provided. One example method comprises exposing the substrate to an activated oxygen species and converting an exposed surface of the substrate into a continuous monolayer of a first dielectric material. The example method also includes forming a second dielectric material on the continuous monolayer of the first dielectric material without exposing the substrate to an air break.

Abstract: Systems and methods of reducing outgassing of a substance within a reaction chamber of a reactor are disclosed. Exemplary methods include depositing a barrier layer within the reaction chamber and using a scavenging precursor to react with species on a surface of the reaction chamber. Exemplary systems include gas-phase deposition systems, such as atomic layer deposition systems, which include a barrier layer source and/or a scavenging precursor source fluidly coupled to a reaction chamber of the system.

Abstract: Systems and methods of reducing outgassing of a substance within a reaction chamber of a reactor are disclosed. Exemplary methods include depositing a barrier layer within the reaction chamber and using a scavenging precursor to react with species on a surface of the reaction chamber. Exemplary systems include gas-phase deposition systems, such as atomic layer deposition systems, which include a barrier layer source and/or a scavenging precursor source fluidly coupled to a reaction chamber of the system.

Abstract: A method for forming a resistive random access memory (RRAM) device is disclosed. The method comprises forming a first electrode, forming a resistive switching oxide layer comprising a metal oxide by thermal atomic layer deposition (ALD) and forming a second electrode by thermal atomic layer deposition (ALD), where the resistive switching layer is interposed between the first electrode and the second electrode. Forming the resistive switching oxide may be performed without exposing a surface of the switching oxide layer to a surface-modifying plasma treatment after depositing the metal oxide.

Abstract: Systems and methods of reducing outgassing of a substance within a reaction chamber of a reactor are disclosed. Exemplary methods include depositing a barrier layer within the reaction chamber and using a scavenging precursor to react with species on a surface of the reaction chamber. Exemplary systems include gas-phase deposition systems, such as atomic layer deposition systems, which include a barrier layer source and/or a scavenging precursor source fluidly coupled to a reaction chamber of the system.

Abstract: The present invention relates to a process and system for depositing a thin film onto a substrate. One aspect of the invention is depositing a thin film metal oxide layer using atomic layer deposition (ALD).

Abstract: A method for forming a resistive random access memory (RRAM) device is disclosed. The method comprises forming a first electrode, forming a resistive switching oxide layer comprising a metal oxide by thermal atomic layer deposition (ALD), doping the resistive switching oxide layer with a metal dopant different from metal forming the metal oxide, and forming a second electrode by thermal atomic layer deposition (ALD), where the resistive switching layer is interposed between the first electrode and the second electrode. In some embodiments, forming the resistive switching oxide may be performed without exposing a surface of the switching oxide layer to a surface-modifying plasma treatment after depositing the metal oxide.

Abstract: A method for forming a resistive random access memory (RRAM) device is disclosed. The method comprises forming a first electrode, forming a resistive switching oxide layer comprising a metal oxide by thermal atomic layer deposition (ALD) and forming a second electrode by thermal atomic layer deposition (ALD), where the resistive switching layer is interposed between the first electrode and the second electrode. Forming the resistive switching oxide may be performed without exposing a surface of the switching oxide layer to a surface-modifying plasma treatment after depositing the metal oxide.

Abstract: The present invention relates to a process and system for depositing a thin film onto a substrate. One aspect of the invention is depositing a thin film metal oxide layer using atomic layer deposition (ALD).

Abstract: Embodiments related to methods for forming a film stack on a substrate are provided. One example method comprises exposing the substrate to an activated oxygen species and converting an exposed surface of the substrate into a continuous monolayer of a first dielectric material. The example method also includes forming a second dielectric material on the continuous monolayer of the first dielectric material without exposing the substrate to an air break.

Abstract: Embodiments related to methods for forming a film stack on a substrate are provided. One example method comprises exposing the substrate to an activated oxygen species and converting an exposed surface of the substrate into a continuous monolayer of a first dielectric material. The example method also includes forming a second dielectric material on the continuous monolayer of the first dielectric material without exposing the substrate to an air break.

Abstract: Improved methods and systems for passivating a surface of a high-mobility semiconductor and structures and devices formed using the methods are disclosed. The method includes providing a high-mobility semiconductor surface to a chamber of a reactor and exposing the high-mobility semiconductor surface to a gas-phase sulfur precursor to passivate the high-mobility semiconductor surface.

Abstract: Embodiments related to methods for forming a film stack on a substrate are provided. One example method comprises exposing the substrate to an activated oxygen species and converting an exposed surface of the substrate into a continuous monolayer of a first dielectric material. The example method also includes forming a second dielectric material on the continuous monolayer of the first dielectric material without exposing the substrate to an air break.

Abstract: Methods of forming metal oxide thin films and related structures are provided. One embodiment of the methods includes conducting a plurality of cycles of deposition on a substrate. Each cycle includes supplying oxygen gas and an inert gas into a reaction space substantially continuously during the cycle. A metal precursor is supplied into the reaction space for a first duration. The metal precursor is a cyclopentadienyl compound of the metal. After the metal precursor is supplied, the continuously flowing oxygen gas is activated for a second duration to generate a plasma in the reaction space. The cycle is conducted at a temperature below about 400° C. The methods can be performed after forming a structure on the substrate, wherein the structure is formed of a material which is physically and/or chemically unstable at a high temperature.

Abstract: In one aspect, non-conformal layers are formed by variations of plasma enhanced atomic layer deposition, where one or more of pulse duration, separation, RF power on-time, reactant concentration, pressure and electrode spacing are varied from true self-saturating reactions to operate in a depletion-effect mode. Deposition thus takes place close to the substrate surface but is controlled to terminate after reaching a specified distance into openings (e.g., deep DRAM trenches, pores, etc.). Reactor configurations that are suited to such modulation include showerhead, in situ plasma reactors, particularly with adjustable electrode spacing.

Abstract: The present invention relates to a process and system for depositing a thin film onto a substrate. One aspect of the invention is depositing a thin film metal oxide layer using atomic layer deposition (ALD).