Abstract: A nanowire of a semiconductor material and having a uniform cross-sectional area along its length is grown using a chemical vapor deposition process. In the method, a substrate is provided, a catalyst nanoparticle is deposited on the substrate, a gaseous precursor mixture comprising a constituent element of the semiconductor material is passed over the substrate, and adatoms of the constituent element are removed from a lateral surface of the nanowire during the passing of the precursor mixture. The removing comprises passing over the substrate a gaseous etchant that forms a volatile compound with the adatoms, the gaseous etchant comprising a halogenated hydrocarbon. Removing the adatoms of the constituent element before such adatoms are incorporated into the nanowire prevents such adatoms from accumulating on the lateral surface of the nanowire and allows the nanowire to grow with a uniform cross-sectional area along its length.

Abstract: Dielectric layers containing a chemical vapor deposited hafnium oxide and an electron beam evaporated lanthanide oxide and a method of fabricating such a dielectric layer produce a reliable dielectric layer having an equivalent oxide thickness thinner than attainable using SiO2. Forming a layer of hafnium oxide by chemical vapor deposition and forming a layer of a lanthanide oxide by electron beam evaporation, where the layer of hafnium oxide is adjacent and in contact with the layer of lanthanide, provides a dielectric layer with a relatively high dielectric constant as compared with silicon dioxide. Forming the layer of hafnium oxide by chemical vapor deposition using precursors that do not contain carbon permits the formation of the dielectric layer without carbon contamination. The dielectric can be formed as a nanolaminate of hafnium oxide and a lanthanide oxide.

Abstract: Low-k dielectric materials are incorporated as an insulator material between bit lines and an inter-level dielectric material. The device is first processed in a known manner, up to and including the deposition and anneal of the bit line metal, using a higher dielectric constant material that can withstand the higher temperature process steps as the insulator between the bit lines. Then, the higher dielectric constant material is removed using an etch that is selective to the bit line metal, and the low-k dielectric material is deposited. The low-k material may then be planarized to the top of the bit lines, and further low-k material deposited as an inter-level dielectric. Alternatively, sufficient low-k material is deposited in a single step to both fill the gaps between the bit lines as well as serve as an inter-level dielectric, and then the low-k dielectric material is planarized. Standard processing may then be carried out.

Abstract: A substrate processing method includes the step of removing carbon from a silicon substrate surface and planarizing the silicon substrate surface from which carbon has been removed.

Abstract: Improved methods and apparatus are provided for the handling and testing of semiconductor devices. One embodiment comprises a die carrier for one or more semiconductor dice having very fine pitch electrical I/O (input/output) elements. The semiconductor dice are temporarily attached to the die carrier in singulated form to enable testing the dice with conventional contact technology. The die carrier may include a flex circuit base substrate and a rigid support frame. Further embodiments comprise materials and methods for attaching the semiconductor dice to the die carrier and for providing a temporary electrical connection with the semiconductor dice during testing. Exemplary materials for providing the temporary electrical connection may comprise a conductive film or tape, a conductive or conductor-filled epoxy, resin or RTV adhesive-based materials, a water-soluble material impregnated with a conductive filler or non-reflowed solder paste.

Abstract: A method of forming a membrane for use in conjunction with a semiconductor carrier and the membrane which includes an electrically insulating substrate and an interconnect pattern formed on the substrate. A stud is coupled to the interconnect pattern over the substrate by forming a gold ball, preferably by gold ball bonding techniques, and coating a portion of the gold ball with a compliant material, preferably an epoxy resin. The coating is filled with a material having sufficient hardness to be capable of penetrating the oxide film on the contact pads of semiconductor devices. The flakes are preferably silver or silver-based.

Abstract: A patterned, multi-layered thin film structure is patterned using ultra-fast lasers and absorption spectroscopy without damaging underlying layers of the layered structure. The structure is made by selecting ablatable layers based on their thermal, strength and absorption spectra and by using an ultra-fast laser programmed with the appropriate wavelength (?), pulse width (?), spectral width (??), spot size, bite size and fluence. The end structure may have features (such as vias, insulating areas, or inkjet printed areas) patterned in the last (top) layer applied or at deeper layers within the layered structure, and can be used as components of organic light emitting didoes (OLEDs) and organic thin film transistors (OTFTs). The method of the present invention includes determining the product's specifications, providing a substrate, selecting a layer, applying the layer, patterning the layer and determining if more layers need to be added to the multi-layered thin film structure.

Abstract: Improved methods and apparatus are provided for the handling and testing of semiconductor devices. One embodiment comprises a die carrier for one or more semiconductor dice having very fine pitch electrical I/O (input/output) elements. The semiconductor dice are temporarily attached to the die carrier in singulated form to enable testing the dice with conventional contact technology. The die carrier may include a flex circuit base substrate and a rigid support frame. Further embodiments comprise materials and methods for attaching the semiconductor dice to the die carrier and for providing a temporary electrical connection with the semiconductor dice during testing. Exemplary materials for providing the temporary electrical connection may comprise a conductive film or tape, a conductive or conductor-filled epoxy, resin or RTV adhesive-based materials, a water-soluble material impregnated with a conductive filler or non-reflowed solder paste.

Abstract: Methods are provided for forming silicon dioxide (SiO2) on a silicon carbide (SiC) substrate. The method comprises: providing a SiC substrate; supplying an atmosphere including oxygen; performing a high-density (HD) plasma-based process; and, forming a SiO2 layer overlying the SiC substrate. Typically, performing the HD plasma-based process includes connecting a top electrode to an inductively coupled HD plasma source. In one aspect, SiO2 is grown on the SiC substrate. Then, an HD plasma oxidation process is performed that creates a reactive oxygen species and breaks the Si—C bonds in the SiC substrate, to form free Si and C atoms in the SiC substrate. The free Si atoms in the SiC substrate are bonded to the HD plasma-generated reactive oxygen species, and the SiO2 layer is grown.

Abstract: Disclosed are various embodiments of a method of forming vias for backside connections in a wafer stack, wherein the vias are formed by non-thermal laser ablation. Other embodiments are described an claimed.

Abstract: This invention is a method comprising providing a substrate, forming a first layer on the substrate, wherein the first layer has a dielectric constant of less than 3.0 and comprises an organic polymer, applying an organosilicate resin over the first layer, removing a portion of the organosilicate resin to expose a portion of the first layer, and removing the exposed portions of the first layer. The invention is also an integrated circuit article comprising an active substrate containing transistors and an electrical interconnect structure containing a pattern of metal lines separated, at least partially, by layers or regions of an organic polymeric material having a dielectric constant of less than 3.0 and further comprising a layer of an organosilicate resin above at least one layer of the organic polymer material.

Abstract: Methods for growing epitaxial silicon are provided. Methods for controlling bottom stacking fault propagation in epitaxial silicon are also provided.

Abstract: A a magnetic random access memory (MRAM) device includes a cap layer formed over a magnetic tunnel junction (MTJ) stack layer, an etch stop layer formed over the first cap layer, and a hardmask layer formed over the etch stop layer. The etch stop layer is selected from a material such that an etch chemistry used for removing the hardmask layer has selectivity against etching the etch stop layer material.

Abstract: A method for manufacturing a semiconductor device including the steps of: forming a hole having a predetermined depth in a semiconductor layer of a first conductivity type in correspondence with a drain region, the semiconductor layer being formed on a semiconductor substrate; forming a diffusion source layer containing impurities of a second conductivity type different from the first conductivity type in the hole; forming a source region of the first conductivity type in a region shallower than the depth of the hole in the semiconductor layer; forming a channel region of the second conductivity type to be disposed between the drain region and the source region in a region deeper than the depth of the source region in the semiconductor layer; and heating the semiconductor substrate to a first temperature after completing the diffusion source layer forming step to diffuse the impurities of the second conductivity type from the diffusion source layer into the channel region, thereby forming a low resistance reg

Abstract: Disclosed is a method for making a metal gate for a FET, wherein the metal gate comprises at least some material deposited by electroplating as well as an FET device comprising a metal gate that is at least partially plated. Further disclosed is a method for making a metal gate for a FET wherein the metal gate comprises at least some plated material and the method comprises the steps of: selecting a substrate having a top surface and a recessed region; conformally depositing a thin conductive seed layer on the substrate; and electroplating a filler gate metal on the seed layer to fill and overfill the recessed region.

Abstract: To provide technology that allows, by controlling a crystal orientation, forming a crystalline semiconductor film aligned in orientation and obtaining a crystalline semiconductor film whose impurity concentration is reduced. On an insulating surface, a first semiconductor region made of an amorphous semiconductor is formed, a continuous wave laser beam is scanned from one end of the first semiconductor region to the other end thereof, thereby the first semiconductor region is once melted and crystallized, thereafter in order to form an active layer of a TFT the first semiconductor region is etched, and thereby a second semiconductor region is formed. In a pattern of the second semiconductor region formed by the etching, in order to improve a field-effect mobility in the TFT, a scanning direction of the laser beam is allowed roughly coinciding with a channel length direction in a thin film transistor.

Abstract: Heat sink structures employing carbon nanotube or nanowire arrays to reduce the thermal interface resistance between an integrated circuit chip and the heat sink are disclosed. Carbon nanotube arrays are combined with a thermally conductive metal filler disposed between the nanotubes. This structure produces a thermal interface with high axial and lateral thermal conductivities.

Abstract: A composite dielectric forming method includes atomic layer depositing alternate layers of hafnium oxide and lanthanum oxide over a substrate. The hafnium oxide can be thermally stable, crystalline hafnium oxide and the lanthanum oxide can be thermally stable, crystalline lanthanum oxide. A transistor may comprise the composite dielectric as a gate dielectric. A capacitor may comprise the composite dielectric as a capacitor dielectric.

Abstract: A method for forming a semiconductor device comprises forming a dielectric layer over a semiconductor wafer substrate assembly having closely-spaced regions, such as a memory transistor array, and widely-spaced regions, such as a periphery. Under conditions specified, the dielectric layer forms to have a first thickness over the closely-spaced regions and a second thickness over the widely-spaced regions. The second thickness is much thinner than the first thickness and dielectric over the widely-spaced regions may be etched away with a blanket etch which leaves the majority of the dielectric layer over the closely-spaced regions.

Abstract: Part of a first oxide film formed by thermal oxidation is removed by etching. A second oxide film is formed in the part of substrate from which the first oxide film has been removed using heated nitric acid. The two oxide films are nitrided by a nitrogen plasma having a low energy so as to be first and second gate insulating films, i.e., oxynitride films, respectively.