Abstract: A siding mounted light clip is described for releasable attachment to a lap type siding member. The clip includes a clip body with a light mount part and a siding mount part. The siding mount part includes a base member with a flange configured to slide under a lap type siding member. A leg member extends from the base member to the light mount part. A resilient clamp member is mounted to the leg member and forms an expandable siding receiving recess with the flange. A lap type siding member may be releasably gripped within the expandable siding receiving recess between the flange and resilient clamp member.

Abstract: In one aspect the invention includes a method of protecting aluminum within an aluminum-comprising layer from electrochemical degradation during semiconductor processing comprising, providing a material within the layer having a lower reduction potential than aluminum. In another aspect, the invention includes a semiconductor processing method of forming and processing an aluminum-comprising mass, comprising: a) forming the aluminum-comprising layer mass to comprise a material having a lower reduction potential than aluminum; and b) exposing the aluminum-comprising mass to an electrolytic substance, the material protecting aluminum within the aluminum-comprising layer from electrochemical degradation during the exposing. In yet another aspect, the invention includes an aluminum-comprising layer over or within a semiconductor wafer substrate and comprising a material having a lower reduction potential than aluminum.

Abstract: In one implementation, A method of forming semiconductive material active area having a proximity gettering region received therein includes providing a substrate comprising bulk semiconductive material. A proximity gettering region is formed within the bulk semiconductive material within a desired active area by ion implanting at least one impurity into the bulk semiconductive material. After forming the proximity gettering region, thickness of the bulk semiconductive material is increased in a blanket manner at least within the desired active area. In one implementation, a method of processing a monocrystalline silicon substrate includes forming a proximity gettering region within monocrystalline silicon of a monocrystalline silicon substrate. After forming the proximity gettering region, epitaxial monocrystalline silicon is formed on the substrate monocrystalline silicon to blanketly increase its thickness at least over the proximity gettering region.

Abstract: Electronic communication devices, methods of forming electrical communication devices, and communications methods are provided. An electronic communication device adapted to receive electronic signals includes: a housing having a substrate and an encapsulant; an integrated circuit provided within the housing and having comprising transponder circuitry operable to communicate an identification signal responsive to receiving a polling signal; an antenna provided within the housing and being coupled with the transponder circuitry; and a ground plane provided within the housing and being spaced from the antenna and configured to shield some of the electronic signals from the antenna and reflect others of the electronic signals towards the antenna.

Abstract: In one aspect the invention includes a method of forming a semiconductor device, comprising: a) forming a layer over a substrate; b) forming a plurality of openings extending into the layer; c) depositing particles on the layer; d) collecting the particles within the openings; and e) using the collected particles as a mask during etching of the underlying substrate to define features of the semiconductor device. In another aspect, the invention includes a method of forming a field emission display, comprising: a) forming a silicon dioxide layer over a conductive substrate; b) forming a plurality of openings extending into the silicon dioxide layer; c) depositing particles on the silicon dioxide layer; d) collecting the particles within the openings; e) while using the collected particles as a mask, etching the conductive substrate to form a plurality of conically shaped emitters from the conductive substrate; and f) forming a display screen spaced from said emitters.

Abstract: A radio frequency identification device comprises an integrated circuit including a receiver, a transmitter, and a microprocessor. The receiver and transmitter together define an active transponder. The integrated circuit is preferably a monolithic single die integrated circuit including the receiver, the transmitter, and the microprocessor. Because the device includes an active transponder, instead of a transponder which relies on magnetic coupling for power, the device has a much greater range.

Abstract: A method of forming a line of FLASH memory cells includes forming a first line of floating gates over a crystalline silicon semiconductor substrate. An alternating series of SiO2 isolation regions and active areas are provided in the semiconductor substrate in a second line adjacent and along at least a portion of the first line of floating gates. The series of active areas define discrete transistor source areas. A masking layer is formed over the floating gates, the regions and the areas. A third line mask opening is formed in the masking layer over at least a portion of the second line. Anisotropic etching is conducted of the SiO2 isolation regions exposed through the third line mask opening substantially selectively relative to crystalline silicon exposed through the third line mask opening using a gas chemistry comprising a combination of at least one non-hydrogen containing fluorocarbon having at least three carbon atoms and at least one hydrogen containing fluorocarbon.

Abstract: A semiconductor processing method of providing a hemispherical grain polysilicon layer atop a substrate includes, a) providing a substantially amorphous layer of silicon over a substrate at a selected temperature; b) raising the temperature of the substantially amorphous silicon layer to a higher dielectric layer deposition temperature, the temperature raising being effective to transform the amorphous silicon layer into hemispherical grain polysilicon; and c) depositing a dielectric layer over the silicon layer at the higher dielectric deposition temperature. Transformation to hemispherical grain might occur during the temperature rise to the higher dielectric layer deposition temperature, after the higher dielectric layer deposition temperature has been achieved but before dielectric layer deposition, or after the higher dielectric layer deposition temperature has been achieved and during dielectric layer deposition.

Abstract: A capacitor processing method includes forming a capacitor comprising first and second electrodes having a capacitor dielectric region therebetween. The first electrode interfaces with the capacitor dielectric region at a first interface. The second electrode interfaces with the capacitor dielectric region at a second interface. The capacitor dielectric region has a plurality of oxygen vacancies therein. After forming the capacitor, an electric field is applied to the capacitor dielectric region to cause oxygen vacancies to migrate towards one of the first and second interfaces. Oxygen atoms are preferably provided at the one interface effective to fill at least a portion of the oxygen vacancies in the capacitor dielectric region. Preferably at least a portion of the oxygen vacancies in the high k capacitor dielectric region are filled from oxide material comprising the first or second electrode most proximate the one interface.

Abstract: The invention includes buried bit line memory circuitry, methods of forming buried bit line memory circuitry, and semiconductor processing methods of forming conductive lines. In but one implementation, a semiconductor processing method of forming a conductive line includes forming a silicon comprising region over a substrate. A TiNx comprising layer is deposited over the silicon comprising region, where “x” is greater than 0 and less than 1. The TiNx comprising layer is annealed in a nitrogen containing atmosphere effective to transform at least an outermost portion of the TiNx layer over the silicon comprising region to TiN. After the annealing, an elemental tungsten comprising layer is deposited on the TiN and at least the elemental tungsten comprising layer, the TiN, and any remaining TiNx layer is patterned into conductive line. In one implementation, a method such as the above is utilized in the fabrication of buried bit line memory circuitry.

Abstract: A method of testing integrated circuitry includes providing a substrate comprising integrated circuitry to be tested. The circuitry substrate to be tested has a plurality of exposed conductors in electrical connection with the integrated circuitry. In one implementation, at least some of the exposed conductors of the circuitry substrate are heated to a temperature greater than 125° C. and within at least 50% in degrees centigrade of and below the melting temperature of the exposed conductors of the circuitry substrate. In one implementation, such are heated to a temperature below their melting temperature yet effective to soften said at least some of the exposed conductors to a point enabling their deformation upon application of less than or equal to 30 grams of pressure per exposed conductor. The circuitry substrate is engaged with a tester substrate.

Abstract: In a weaving device, a weaving device frame mounts a plurality of eyelets. A frame module, releasably borne by the weaving device frame is readily detachable from and controls movement of the respective eyelets. The frame module forms a readily removable component of the weaving device.

Abstract: Semiconductor processing methods of forming integrated circuitry, and in particular, dynamic random access memory (DRAM) circuitry are described. In one embodiment, a single masking step is utilized to form mask openings over a substrate, and both impurities are provided and material of the substrate is etched through the openings. In one implementation, openings are contemporaneously formed in a photo masking layer over substrate areas where impurities are to be provided, and other areas where etching is to take place. In separate steps, the substrate is doped with impurities, and material of the substrate is etched through the mask openings. In another implementation, two conductive lines are formed over a substrate and a masking layer is formed over the conductive lines. Openings are formed in the masking layer in the same step, with one of the openings being received over one conductive line, and another of the openings being received over the other conductive line.

Abstract: The invention encompasses a method of forming bitlines. A substrate is provided, and comprises a plurality of spaced electrical nodes. A bitline layer is formed over at least some of the spaced electrical nodes. The bitline layer comprises at least one conductive material. Openings are etched through the bitline layer and to the electrical nodes. After the openings are formed, the bitline layer is patterned into bitlines. The invention also encompasses a method of forming a capacitor and bitline structure. A substrate is provided, and comprises a plurality of spaced electrical nodes. A stack of bitline materials is formed over at least some of the spaced electrical nodes. The bitline materials comprise at least one insulative material over at least one conductive material. Openings are etched through the bit line materials and to the electrical nodes. Conductive masses are formed in at least some of the openings. After the conductive masses are formed, the bitline materials are patterned into bitlines.

Abstract: A chemical vapor deposition method of forming a high k dielectric layer includes positioning a substrate within a chemical vapor deposition reactor. At least one metal comprising precursor and N2O are provided within the reactor under conditions effective to deposit a high k dielectric layer on the substrate comprising oxygen and the metal of the at least one metal precursor. The N2O is present within the reactor during at least a portion of the deposit at greater than or equal to at least 90% concentration by volume as compared with any O2, O3, NO, and NOX injected to within the reactor. In one implementation, the conditions are void of injection of any of O2, O3, NO, and NOX to within the reactor during the portion of the deposit. In one implementation, a capacitor is formed using the above methods. In preferred implementations, the technique can be used to yield smooth, continuous dielectric layers in the absence of haze or isolated island-like nuclei.

Abstract: The invention includes methods of forming titanium comprising layers, and methods of forming conductive silicide contacts. In one implementation, a method of forming a titanium comprising layer includes chemical vapor depositing a layer a majority of which comprises elemental titanium, titanium silicide or a mixture thereof over a substrate using a precursor gas chemistry comprising titanium and chlorine. The layer comprises chlorine from the precursor gas chemistry. The layer is exposed to a hydrogen containing plasma effective to drive chlorine from the layer. In one implementation, a method of forming a conductive silicide contact includes forming an insulating material over a silicon comprising substrate. An opening is formed into the insulating material over a node location on the silicon comprising substrate to which electrical connection is desired. A layer is chemical vapor deposited over the substrate using a precursor gas chemistry comprising titanium and chlorine.

Abstract: In accordance with an aspect of the invention, a transistor is formed having a transistor gate, a gate dielectric layer and source/drain regions. The transistor gate includes at least two conductive layers of different conductive materials. One of the two conductive layers is more proximate the gate dielectric layer than the other of the two conductive layers. A source/drain reoxidation is conducted prior to forming the other conductive layer. In another aspect of the invention, a transistor has a transistor gate, a gate dielectric layer and source/drain regions. The transistor gate includes a tungsten layer. A source/drain reoxidation is conducted prior to forming the tungsten layer of the gate. In yet another aspect of the invention, a semiconductor processing method forms a transistor gate having insulative sidewall spacers thereover. After forming the insulative sidewall spacers, an outer conductive tungsten layer of the transistor gate is formed.

Abstract: Methods of forming contact openings, memory circuitry, and dynamic random access memory (DRAM) circuitry are described. In one implementation, an array of word lines and bit lines are formed over a substrate surface and separated by an intervening insulative layer. Conductive portions of the bit lines are outwardly exposed and a layer of material is formed over the substrate and the exposed conductive portions of the bit lines. Selected portions of the layer of material are removed along with portions of the intervening layer sufficient to (a) expose selected areas of the substrate surface and to (b) re-expose conductive portions of the bit lines. Conductive material is subsequently formed to electrically connect exposed substrate areas with associated conductive portions of individual bit lines.

Abstract: The invention includes a semiconductor processing method which comprises forming a first material layer over a substrate. A second material layer is formed over the first material layer. Photoresist is deposited over the second material layer, and an opening is formed within the photoresist to the second material layer. The second material layer is etched through the photoresist opening to a degree insufficient to outwardly expose the first material layer. The photoresist is then stripped from the substrate. Subsequently, the second material layer and the first material layer are blanket etched.

Abstract: In one aspect, the invention encompasses a transistor device comprising a region of a semiconductor material wafer, and a transistor gate over a portion of the region. The transistor gate has a pair of opposing sidewalls which are a first sidewall and a second sidewall. The device further comprises a pair of opposing sidewall spacers adjacent the sidewalls of the transistor gate and a pair of opposing first conductivity type source/drain regions within the semiconductor material wafer proximate the transistor gate. One of the sidewall spacers extends along the first sidewall of the gate and the other of the sidewall spacers extends along the second sidewall of the gate. The entirety of the semiconductor wafer material under one of the sidewall spacers being defined as a first segment of the semiconductor wafer material, and the entirety of the semiconductor wafer material which is under the other of the sidewall spacers being defined as a second segment of the semiconductor wafer material.