Abstract: This invention allows for the deposition of aluminum nitride buffer layers and templating films that greatly enhance the quality of additional aluminum nitride deposited by alternate deposit ion techniques and reduce the overall thickness of needed buffer layers. Furthermore, these films can be deposited at substrate temperatures of 400° C. and 580° C. which is considerably lower than other techniques, such as molecular beam epitaxy (MBE) and metal organic chemical vapor deposition (MOCVD).

Abstract: A method of forming a conformal layer including TiN in a via includes introducing a precursor into a reaction chamber according to a first exposure schedule. The precursor includes non-halogenated metal-organic titanium. The first exposure schedule indicates precursor exposure periods. Each precursor exposure period is associated with a particular duration of time and a particular duty cycle over which to introduce the precursor during the particular duration of time. The method includes introducing a co-reactant into the reaction chamber according to a second exposure schedule. The co-reactant includes nitrogen. The second exposure schedule indicates co-reactant exposure periods. Each co-reactant exposure period is associated with a particular duration of time and a particular duty cycle over which to introduce the co-reactant during the particular duration of time. The method includes providing the conformal layer including TiN in the via based on said introducing the precursor and the co-reactant.

Abstract: Described are low resistivity metal layers/films, such as low resistivity ruthenium (Ru) layers/films, and methods of forming low resistivity metal films. Ru layers/films with close-to-bulk resistivity can be prepared on substrates using Ru(CpEt)2 + O2 ALD, as well as a two-step ALD process using Ru(DMBD)(CO)3 + TBA (tertiary butyl amine) to nucleate the substrate and Ru(EtCp)2 + O2 to increase layer/film thickness. The Ru layer/films and methods of preparing Ru layers/films described herein may be suitable for use in barrierless via-fills, as well as at M0/M1 interconnect layers.

Abstract: An N-bit non-volatile multi-level memory cell (MLC) can include a lower electrode and an upper electrode spaced above the lower electrode. N ferroelectric material layers can be vertically spaced apart from one another between the lower electrode and the upper electrode, wherein N is at least 2 and at least one dielectric material layer having a thickness of less than 20 nm can be located between the N ferroelectric material layers.

Abstract: A semiconductor structure includes a nanofog oxide adhered to an inert 2D or 3D surface or a weakly reactive metal surface, the nanofog oxide consisting essentially of 0.5-2 nm Al2O3 nanoparticles. The nanofog can also consists of sub 1 nm particles. Oxide layers can be formed on the nanofog, for example a bilayer stack of Al2O3—HfO2. Additional examples are from the group consisting of ZrO2, HfZrO2, silicon or other doped HfO2 or ZrO2, ZrTiO2, HfTiO2, La2O3, Y2O3, Ga2O3, GdGaOx, and alloys thereof, including the ferroelectric phases of HfZrO2, silicon or other doped HfO2 or ZrO2. The structure provides the basis for various devices, including MIM capacitors, FET transistors and MOSCAP capacitors.

Abstract: Provided by the inventive concept are methods for fabricating semiconductor devices, such as methods of atomic layer deposition (ALD). Aspects of the inventive concept include methods for depositing and forming Ru metal layers having low resistivity, forming Ru metal layers without the need for a post-deposition annealing step, forming Ru metal layers selectively on portions of a substrate without the need for passivation, and providing Ru metal layers for use in back end of the line (BEOL) applications in semiconductor devices that do not require a liner/barrier layer.

Abstract: Methods of bonding and structures with such bonding are disclosed. One such method includes providing a first substrate with a first electrical contact; providing a second substrate with a second electrical contact above the first electrical contact, wherein an upper surface of the first electrical contact is spaced apart from a lower surface of the second electrical contact by a gap; and depositing a layer of selective metal on the lower surface of the second electrical contact and on the upper surface of the first electrical contact by a thermal Atomic Layer Deposition (ALD) process until the gap is filled to create a bond between the first electrical contact and the second electrical contact.

Abstract: The present inventive concept relates to selective metal layer deposition. Embodiments include a method for atomic layer deposition (ALD) of a metal, the method comprising at least one cycle of: a) exposing a substrate, the substrate comprising a surface comprising a metal portion and an insulator portion, to a metal-organic precursor; b) depositing a metal-organic precursor on an upper surface of the metal portion of the substrate to selectively provide a metal precursor layer on the upper surface of the metal portion of the substrate; c) exposing the metal precursor layer to a co-reactant; and d) depositing the co-reactant on the metal precursor layer, wherein the co-reactant takes part in a ligand exchange with the metal precursor layer.

Abstract: A method for forming a high-k oxide includes forming a nanofog of Al2O3 nanoparticles and conducting subsequent ALD deposition of a dielectric on the nanofog. A nanofog oxide is adhered to an inert 2D or 3D surface, the nano oxide consisting essentially of sub 1 nm Al2O3 nanoparticles. Additional oxide layers can be formed on the nanofog. Examples are from the group of selected from the group consisting of ZrO2, HfZrO2, silicon or other doped HfO2 or ZrO2, ZrTiO2, HfTiO2, La2O3, Y2O3, Ga2O3, GdGaOx, and alloys thereof, including the ferroelectric phases of HfZrO2, silicon or other doped HfO2 or ZrO2.

Abstract: Provided are high quality metal-nitride, such as aluminum nitride (AlN), films for heat dissipation and heat spreading applications, methods of preparing the same, and deposition of high thermal conductivity heat spreading layers for use in RF devices such as power amplifiers, high electron mobility transistors, etc. Aspects of the inventive concept can be used to enable heterogeneously integrated compound semiconductor on silicon devices or can be used in in non-RF applications as the power densities of these highly scaled microelectronic devices continues to increase.

Abstract: An N-bit non-volatile multi-level memory cell (MLC) can include a lower electrode and an upper electrode spaced above the lower electrode. N ferroelectric material layers can be vertically spaced apart from one another between the lower electrode and the upper electrode, wherein N is at least 2 and at least one dielectric material layer having a thickness of less than 20 nm can be located between the N ferroelectric material layers.

Abstract: A composition comprising silica shells conjugated to a TLR7 agonist and methods of using the composition are provided.

Abstract: The present disclosure provides a method of forming a nanolaminate structure. First, a pre-treatment is performed on a semiconductor substrate, in which the semiconductor substrate includes SiGe. Then, a first metal oxide layer is formed on the semiconductor substrate. Then, at least one second metal oxide layer and at least one third metal oxide layer are alternately stacked on the first metal oxide layer, thereby forming a nanolaminate structure. And, a conductive gate layer is formed on the nanolaminate structure.

Abstract: The present inventive concept is related to methods for passivating an oxide layer and methods of selectively depositing a metal, metal nitride, metal oxide, or metal silicide layer on a metal, metal oxide, or silicide layer over an oxide layer including exposing the oxide layer to a passivant that selectively binds to the oxide layer over the metal, metal oxide, or silicide layer, and selectively growing the metal, metal nitride, metal oxide or metal silicide layer on the metal, metal oxide or silicide layer.

Abstract: Embodiments of the disclosure relate to selective metal silicide deposition methods. In one embodiment, a substrate having a silicon containing surface is heated and the silicon containing surface is hydrogen terminated. The substrate is exposed to sequential cycles of a MoF6 precursor and a Si2H6 precursor which is followed by an additional Si2H6 overdose exposure to selectively deposit a MoSix material comprising MoSi2 on the silicon containing surface of the substrate. Methods described herein also provide for selective native oxide removal which enables removal of native oxide material without etching bulk oxide materials.

Abstract: Embodiments of the disclosure relate to selective metal silicide deposition methods. In one embodiment, a substrate having a silicon containing surface is heated and the silicon containing surface is hydrogen terminated. The substrate is exposed to sequential cycles of a MoF6 precursor and a Si2H6 precursor which is followed by an additional Si2H6 overdose exposure to selectively deposit a MoSix material comprising MoSi2 on the silicon containing surface of the substrate.

Abstract: Embodiments described herein relate to semiconductor and metal substrate surface preparation and controlled growth methods. An example application is formation of an atomic layer deposition (ALD) control layer as a diffusion barrier or gate dielectric layer and subsequent ALD processing. Embodiments described herein are believed to be advantageously utilized concerning gate oxide deposition, diffusion barrier deposition, surface functionalization, surface passivation, and oxide nucleation, among other processes. More specifically, embodiments described herein provide for silicon nitride ALD processes which functionalize, passivate, and nucleate a SiNx monolayer at temperatures below about 300° C.

Abstract: Embodiments of the disclosure relate to selective metal silicide deposition methods. In one embodiment, a substrate having a silicon containing surface is heated and the silicon containing surface is hydrogen terminated. The substrate is exposed to sequential cycles of a MoF6 precursor and a Si2H6 precursor which is followed by an additional Si2H6 overdose exposure to selectively deposit a MoSix material comprising MoSi2 on the silicon containing surface of the substrate. Methods described herein also provide for selective native oxide removal which enables removal of native oxide material without etching bulk oxide materials.

Abstract: Embodiments of the disclosure relate to selective metal silicide deposition methods. In one embodiment, a substrate having a silicon containing surface is heated and the silicon containing surface is hydrogen terminated. The substrate is exposed to sequential cycles of a MoF6 precursor and a Si2H6 precursor which is followed by an additional Si2H6 overdose exposure to selectively deposit a MoSix material comprising MoSi2 on the silicon containing surface of the substrate.

Abstract: Surface pretreatment of SiGe or Ge surfaces prior to gate oxide deposition cleans the SiGe or Ge surface to provide a hydrogen terminated surface or a sulfur passivated (or S—H) surface. Atomic layer deposition (ALD) of a high-dielectric-constant oxide at a low temperature is conducted in the range of 25-200° C. to form an oxide layer. Annealing is conducted at an elevated temperature. A method for oxide deposition on a damage sensitive III-V semiconductor surface conducts in-situ cleaning of the surface with cyclic pulsing of hydrogen and TMA (trimethyl aluminum) at a low temperature in the range of 100-200° C. Atomic layer deposition (ALD) of a high-dielectric-constant oxide forms an oxide layer. Annealing is conducted at an elevated temperature. The annealing can create a silicon terminated interfaces.