Abstract: A new method of fabricating a stacked gate Flash EEPROM device having an improved interpoly oxide layer is described. A gate oxide layer is provided on the surface of a substrate. A first polysilicon layer is deposited overlying the gate oxide layer and patterned to form a floating gate. Source and drain regions associated with the floating gate are formed within the substrate. An oxide layer is deposited overlying the floating gate and the substrate. The oxide layer is polished away until the top of the oxide layer is even with the top of the floating gate. A second polysilicon layer is deposited overlying the oxide layer and the first polysilicon layer of the floating gate wherein the second polysilicon layer has a smooth surface. An interpoly dielectric layer is deposited overlying the second polysilicon layer. A third polysilicon layer is deposited overlying the interpoly dielectric layer.

Abstract: A method for fabricating a boron-contained silicate glass layers, such as borosilicate and borophosphosilicate glass films at low temperature using High Density Plasma CVD with silane derivatives as a source of silicon, boron and phosphorus compounds as a doping compounds, oxygen is described. RF plasma with certain plasma density is maintained throughout the entire deposition step in reactor chamber. Key feature of the invention's process is a flow capability of boron-contained silicate glass materials which provide a film with good film integrity and void-free gap-fill within the steps of device structures after low temperature thermal budget anneal conditions.

Abstract: The invention teaches a method of forming an improved liquid-crystal-on-silicon display. The device structure is enhanced by the creation of silicon nitride alignment posts using methods of photolithography, the alignment posts are located among the pixels of the microdisplay.

Abstract: A method of for electroless copper deposition using a Pd/Pd acetate seeding layer formed in using only two components (Pd acetate and solvent) to form an interconnect for a semiconductor device. The invention has two preferred embodiments. The first embodiment forms a Key seed layer composed of Pd/Pd acetate by a spin-on or dip process for the electroless plating of a Cu plug. The second embodiment forms a Pd passivation cap layer over the Cu plug to prevent the Cu plug from oxidizing.

Abstract: A semiconductor chip device package comprised of a semiconductor substrate having semiconductor devices formed on the semiconductor substrate. At least one dielectric layer is over the semiconductor substrate. At least one layer of interconnects is over the semiconductor devices and within the at least one respective dielectric layer with at least a portion of the interconnects being separated by voids having a vacuum or air therein. A passivation layer is over the uppermost of the at least one layer of interconnects. Wherein the semiconductor chip device is vacuum sealed within a semiconductor chip device package.

Abstract: In accordance with the objectives of the invention a new package is provided that is provided with a cavity that is shaped such that more than one semiconductor device can in a vertical direction be mounted in the cavity of the package. The devices that are mounted inside the cavity of the package are separated by separate components of insulation, the overlying devices are electrically interconnected by horizontally positioned solder bumps and vertical interconnect plugs.

Abstract: A process for forming a high dielectric constant, (High K), layer, for a metal-oxide-metal, capacitor structure, featuring localized oxidation of an underlying metal layer, performed at a temperature higher than the temperature experienced by surrounding structures, has been developed. A first iteration of this process features the use of a laser ablation procedure, performed to a local region of an underlying metal layer, in an oxidizing ambient. The laser ablation procedure creates the desired, high temperature, only at the laser spot, allowing a high K layer to be created at this temperature, while the surrounding structures on a semiconductor substrate, not directly exposed to the laser ablation procedure remain at lower temperatures.

Abstract: A method for forming dual-damascene type conducting interconnects with non-metallic barriers that protect said interconnects from fluorine out-diffusion from surrounding low-k, fluorinated dielectric materials. One embodiment of the method is particularly suited for forming such interconnects in microelectronics fabrications of the sub 0.15 micron generation.

Abstract: A new method and apparatus is provided that assures constant fluid flow of the fluid that is entered into a semiconductor device processing tank or container. A flow meter is set to a particular flow rate; the fluid that comes from the POU is routed through the flow meter. The fluid passes through a flow meter into a processing tank. The fluid is allowed to fill the container up to an overflow point of the container. An overflow basin is provided into which the overflowing fluid is routed from where the fluid is drained into a fluid reclaim vessel. The overflow is detected by a sensor, the sensor activates an overflow relieve valve that is mounted in the bottom of the container. The overflow relieve valve is opened and drains fluid from the container thus counteracting the overflow of the fluid into the overflow basin. The interaction between the overflow detector and the overflow relieve valve assures a constant rate of supply of the fluid to the processing tank or container.

Abstract: A method for forming a CMOS transistor gate with a self-aligned. channel implant. A semiconductor structure having a first active area is provided. A first insulating layer is formed on the semiconductor structure, and a second insulating layer is formed on the first insulating layer. The second insulating layer is patterned using a poly reverse mask and an etch selective to the first insulating layer to form a first channel implant opening, and the poly reverse mask is removed. A first channel implant mask is formed exposing the first channel implant opening. Impurity ions are implanted through the first channel implant opening to form a first threshhold adjust region and a first anti-punchthrough region. A gate layer is formed over the semiconductor structure, and the first gate layer is planarized to form a gate electrode. The second insulating layer is removed, and lightly doped source and drain regions, sidewall spacers and source and drain regions can be formed adjacent the gate electrode.

Abstract: A method for forming logic circuits with embedded memory is described. Isolation areas are formed on a semiconductor substrate separating at least one logic area and at least one memory area. Gate electrode stacks comprising a polysilicon layer, a silicide layer, a first oxide layer, and a first nitride layer are formed in the device areas. The semiconductor substrate and the gate electrode stacks are covered with a first mask. The first mask in the logic areas is partially removed to expose the first nitride layer. The first nitride layer is removed to expose the first oxide layer in the logic areas. The first mask is removed. Processing continues to form LDD regions, S/D regions in the logic areas, and memory devices in the memory areas. Since the first nitride layer in the logic areas has been removed, an etching with an etch stop at nitride can form metal contacts in the logic areas and memory areas simultaneously.

Abstract: A new method is provided for the creation of a horizontal spiral inductor over the surface of a silicon substrate. A first layer of dielectric is deposited over the surface of the substrate, this first layer of dielectric is patterned and etched creation islands of first dielectric material overlying the surface of the substrate, the islands of first dielectric material align with coils of a thereover to be created spiral inductor. The openings created in the layer of dielectric by the patterning and etching of the first layer of dielectric are filled by selective deposition of epitaxial silicon therein. Second and third layers of dielectric are successively deposited over the surface of the first layer of dielectric. A spiral horizontal inductor is then created over the surface of the third layer of dielectric.

Abstract: A new method of forming a metal oxide high dielectric constant layer in the manufacture of an integrated circuit device has been achieved. A substrate is provided. A metal oxide layer is deposited overlying the substrate by reacting a precursor with an oxidant gas in a chemical vapor deposition chamber. The metal oxide layer may comprise hafnium oxide or zirconium oxide. The precursor may comprise metal alkoxide, metal alkoxide containing halogen, metal &bgr;-diketonate, metal fluorinated &bgr;-diketonate, metal oxoacid, metal acetate, or metal alkene. The metal oxide layer is annealed to cause densification and to complete the formation of the metal oxide dielectric layer in the manufacture of the integrated circuit device. A composite metal oxide-silicon oxide (MO2-SiO2) high dielectric constant layer may be deposited using a precursor comprising metal tetrasiloxane.

Abstract: A method for forming an electrostatic discharge device using silicon-on-insulator technology is described. An N-well is formed within a silicon semiconductor substrate. A P+ region is implanted within a portion of the N-well and an N+ region is implanted within a portion of the semiconductor substrate not occupied by the N-well. An oxide layer is formed overlying the semiconductor substrate and patterned to form openings to the semiconductor substrate. An epitaxial silicon layer is grown within the openings and overlying the oxide layer. Shallow trench isolation regions are formed within the epitaxial silicon layer extending to the underlying oxide layer. Gate electrodes and associated source and drain regions are formed in and on the epitaxial silicon layer between the shallow trench isolation regions. An interlevel dielectric layer is deposited overlying the gate electrodes. First contacts are opened through the interlevel dielectric layer to the underlying source and drain regions.

Abstract: A method of forming a self-aligned elevated transistor using selective epitaxial growth is described. An oxide layer is provided overlying a semiconductor substrate. The oxide layer is etched through to the semiconductor substrate to form a trench having a lower portion contacting the substrate and an upper portion having a width larger than the width of the lower portion. A silicon layer is grown within the trench using selective epitaxial growth wherein the silicon layer fills the lower portion and partially fills the upper portion. Nitride spacers are formed on the sidewalls of the trench. A polysilicon layer is deposited overlying the oxide layer and within the trench and etched back to form a gate electrode within the trench between the nitride spacers. The nitride spacers are etched away where they are not covered by the gate electrode leaving thin nitride spacers on sidewalls of the gate electrode.

Abstract: Described is a system designed to warm the transfer chamber used in vacuum equipment in the manufacture of integrated circuits during maintenance. The system detects when the transfer chamber lid is opened and the chamber is exposed to the atmosphere. This activates the heater normally used to bake out the chamber. A temperature sensor is used to keep the temperature below a set point. By warming the chamber, moisture build-up on the inside of the chamber during maintenance is minimized, thereby reducing out gassing and time required to bring the chamber back to its base vacuum pressure when returned to production.

Abstract: Methods for forming dual-metal gate CMOS transistors are described. An NMOS and a PMOS active area of a semiconductor substrate are separated by isolation regions. A metal layer is deposited over a gate dielectric layer in each active area. Silicon ions are implanted into the metal layer in one active area to form an implanted metal layer which is silicided to form a metal silicide layer. Thereafter, the metal layer and the metal silicide layer are patterned to form a metal gate in one active area and a metal silicide gate in the other active area wherein the active area having the gate with the higher work function is the PMOS active area. Alternatively, both gates may be metal silicide gates wherein the silicon concentrations of the two gates differ. Alternatively, a dummy gate may be formed in each of the active areas and covered with a dielectric layer. The dielectric layer is planarized thereby exposing the dummy gates. The dummy gates are removed leaving gate openings to the semiconductor substrate.

Abstract: A new method and apparatus for detecting and measuring the level of metal present on the surface of a substrate is achieved. Energy, in the form of rf or light or microwave energy, is directed at the surface of a wafer, the reflected energy or the energy that passes through the semiconductor substrate is captured and analyzed for energy level and/or frequency content. Based on this analysis conclusions can be drawn regarding presence and type of metal on the surface of the wafer. Furthermore, by inclusion of metal within the resonating circuit of an rf generator changes the frequency of the vibration and therefore detects the presence of metal.

Abstract: An improved etch sequence and an improved integration scheme of plasma doping in the fabrication of a DRAM integrated circuit device are described. Semiconductor device structures are provided in and on a substrate wherein the substrate is divided into an array area and a periphery area. The semiconductor device structures are covered with a dielectric layer. The dielectric layer is concurrently etched through in the array area to form bit line contact openings and in the periphery area to form substrate contact openings. Doped regions are formed in the substrate exposed within the bit line contact openings and the substrate contact openings using a plasma doping process. Next, the dielectric layer is etched through to form a gate contact opening. Thereafter, the bit line contact openings, the substrate contact openings, and the gate contact opening are filled with a conducting layer to complete forming contacts in the fabrication of a DRAM integrated circuit.

Abstract: A new method of forming a dual damascene interconnect structure, wherein damage of interconnect and contamination of dielectrics during etching is minimized by having an embedded organic stop layer over the lower interconnect and later etching the organic stop layer with an H2 containing plasma, or hydrogen radical.