Abstract: A capacitor for a semiconductor device is formed by selectively processing a portion of a layer (41, 113) to form an electrode (411, 81, 101, 111) for the capacitor. The selective processing includes selective doping, selective silicidation, selective oxidation, or the like. Contacts can be made to the electrode (411) with a reduced likelihood of the contact electrically shorting the electrodes of the capacitor together. When forming contact openings, misalignment tolerance is increased.

Abstract: A method of sensing a particle in a mixture includes providing (52) the mixture (36) having a particle (29, 30), moving (54) the mixture (36) in a direction, shining (56) a light into a portion of the moving mixture (36), reflecting a portion of the light off of the particle (29, 30) in the moving mixture (36), detecting and measuring (57) the reflected light, and using (58) the measured reflected light to determine a size of the particle (29, 30).

Abstract: An annealed amorphous silicon layer is formed prior to forming field isolation regions when using in a LOCOS field isolation process. The annealed amorphous silicon layer helps to reduce encroachment compared to conventional LOCOS field isolation process and helps to reduce the likelihood of forming pits within a substrate compared to a PBL field isolation process. The annealed amorphous silicon layer may be used in forming field isolation regions that defines the active regions between transistors including MOSFETs and bipolar transistors. Doped silicon or a silicon-rich silicon nitride layer may be used in place of conventional materials. The anneal of the amorphous silicon layer may be performed after forming a silicon nitride layer if the silicon nitride layer is deposited at a temperature no higher than 600 degrees Celsius.

Abstract: A semiconductor device is formed having a floating gate memory cell (11) that has its channel region (33) oriented vertically with a portion of the channel region (33) that is not capacitively coupled to a floating gate (32). The memory cell (11) is less likely to be over-erased and may be programmed by source-side injection. The cell (11) may not need to be repaired after erasing. Less power may be consumed during programming compared to hot electron injection and Fowler-Nordheim tunneling.

Abstract: A static-random-access memory (SRAM) cell has been devised which contains an access transistor having a first channel region with a first surface that lies along a first crystal plane; and a trench driver transistor having a second channel region with a second surface that lies along a second crystal plane. The first and second crystal planes belong to a single family of equivalent crystal planes, for example, the {100} family of planes. Orienting the surfaces of the channel regions of the two transistors in this fashion improves the beta ratio of the driver and access transistors and thus greatly improves the cell stability. The .beta. ratio is the ratio of the transconductances of the driver and access MOSFETs, or ##EQU1## and preferably has a value of at least three. Using a trench driver transistor improves the bit cell capacitance.

Abstract: A capacitor with a metal-oxide dielectric layer is formed with an upper electrode layer that is electrically connected to an underlying circuit element. The capacitor may be used in forming storage capacitors for DRAM and NVRAM cells. After forming an underlying circuit element, such as a source/drain region of a transistor, a metal-oxide capacitor is formed over the circuit element. An opening is formed through the capacitor and extends to the circuit element. An insulating spacer is formed, and a conductive member is formed that electrically connects the circuit element to the upper electrode layer of the metal-oxide capacitor. Devices including DRAM and NVRAM cells and methods of forming them are disclosed.

Abstract: A layer over a patterned semiconductor is polished and analyzed to determine a polishing endpoint. The analysis may be performed using reflected radiation beams or by a radiation scattering analyzer. The analysis may be performed on virtually any layer using a radiation source. The analysis may be performed with a liquid, such as an aqueous slurry, contacting the substrate. The polishing and analysis may be integrated such that both steps are performed on the same polisher.

Abstract: A body-tied MOSFET (14) is used in a protection circuit (10) of an SOI device (20) where the MOSFET's drain regions (38) lie outside MOSFET's closed-gate electrode (34). Electrical characteristics of the body-tied MOSFET (14) can be changed by varying the ratio of the total source region area to the total body-tied region area (tie frequency). The total electrical device width is the sum of the individual source region (36) widths. More charge can be placed on the drain region (38) compared to a drain region on the inside because the interfacial area between the drain region and channel region is larger. The device (20) can be formed without having to develop new processing steps or use marginal processing steps. Body ties to an underlying substrate are unnecessary.

Abstract: The present invention includes a modified polishing pad and methods on how to form and use the polishing pad. In one embodiment, a modified polishing pad is formed similar to polishing substrates except that the modifying pressure should be large enough to mechanically deform part of the polishing pad. The modifying pressure is typically at least 10 pounds per square inch. The materials used to modify the pad should be hard with a smooth surface. Examples of these materials are metals, dielectrics, and semiconductors. After modifying the polishing pad, it may be used to polish semiconductor substrates. Compared to a fresh pad, the modified polishing pad should have a higher planarization efficiency and be less likely to cause corner rounding of a patterned layer adjacent to an opening.

Abstract: Interconnects (22 and 32) are formed within an insulating base material of a first substrate. Trenches (54) and portions of an insulating layer (52) are formed within a second substrate (50). The two substrates are bonded by fusion. The second substrate is polished back to form semiconductor islands (81-83) over the first substrate. Active regions of transistors are formed within the islands (81-83). Conductive plugs (131-134) are made between portions of the active regions and interconnects (22, 32, and 141) that underlie or overlie the semiconductor islands (81-83). Embodiments of the present invention allow higher component density, better thickness control for SOI regions, and lower leakage current compared to SOI layers that use LOCOS-type field isolation.

Abstract: Narrow and wide, planar field isolation region (72, 74, 152, 172, 182) is formed by forming trenches (52, 54) within a substrate (10). For wide, planar field isolation regions (72, 152, 172, 182), the trenches (52) define at least one mesa (76, 150, 170, 180) within the field isolation region (72, 152, 172, 182). The trenches (52, 54) are filled with a material (62) that is polished or etched to form the planar field isolation region (72, 74, 152, 172, 182) where the wide, planar field isolation regions (72, 152, 172, 182) include the mesa(s) (76, 150, 170, 180). Etching can be used or by polishing with minimal, if any, dishing occurs because the widths of the trenches (52, 54) are kept relatively narrow (usually no more than five microns wide). Mesas (180) within a wide, planar field isolation region (182) can form linguistic characters to better identify the part number or mask set of the device.

Abstract: Bond pads (394, 106) and bond pad openings (62, 108) are formed such that the bond pad openings (62, 108) are asymmetric to the conductive sections (398, 106) of the bond pads (394, 106). If the bond pads are more likely to lift from the scribe line side of the bond pad (394, 106), the bond pad openings (62, 108) are formed such that the passivation layer (52) overlies more of the conductive section (398, 106) near the scribe line (40). If the bond pads (394, 106) are more likely to lift from the other side, the passivation layer (52) overlies more of the other side of the conductive section (398, 106). In addition to reducing the risk of lifting, contamination problems should also be reduced.

Abstract: A mold is used to form a polishing pad, wherein the surface of the polishing side of the polishing pad is determined by a primary surface of the mold. Features along the polishing side of a polishing pad may take any one of several different shapes. Channels along the polishing side of the polishing pad allow a smaller pore size to be used. The mold allows more control over the surface of the polishing side, which in turn give more control over polishing characteristics.

Abstract: An aluminum-nickel-chromium (Al-Ni-Cr) layer used as an interconnect within a semiconductor device is disclosed. The Al-Ni-Cr layer has about 0.1-0.5 weight percent nickel and about 0.02-0.1 weight percent chromium. Usually, the nickel or chromium concentrations are no greater than 0.5 weight percent. The layer is resistant to electromigration and corrosion. The low nickel and chromium concentrations allow the layer to be deposited and patterned similar to most aluminum-based layers.

Abstract: EPROM cells include T-shaped floating gates (61, 171) and control gates that surround virtually all of the floating gates (61, 171) except for the portion of the floating gates (61, 171) that lie on a gate dielectric layer (51, 151). The EPROM cells may include customized well regions (22, 122) to allow flash erasing or individual cell erasing for electrically erasable EPROMs. Many different configurations of the memory cells are possible. The configurations of the source regions, drain regions, and well regions (22, 122) may be determined by how a user of the memory cells wants to program or erase the memory cells.

Abstract: A floating gate (51)is formed to have a cavity (52) that increases the capacitive coupling between the floating gate (51) and a control gate for the memory cell. The memory cell may be used in EPROM, EEPROM, and flash EEPROM arrays and may be programmed and erased by hot carrier injection, Fowler-Nordheim tunneling or the like. The process sequence for forming the cavity (52) of the floating gate (51) has good process margin allowing some lithographic misalignment. In one embodiment, a multi-tiered floating gate may be formed. The multi-tier structure allows the capacitive coupling to further increase without occupying more area.

Abstract: A process for fabricating a graded-channel MOS device includes the formation of a masking layer (16) on the surface of a semiconductor substrate (10) and separated from the surface by a gate oxide layer (12). A first doped region (22) is formed in a channel region (20) of the semiconductor substrate (10) using the masking layer (16) as a doping mask. A second doped region (24) is formed in the channel region (20) and extends from the principal surface (14) of the semiconductor substrate (10) to the first doped region (22). A gate electrode (34) is formed within an opening (18) in the masking layer (16) and aligned to the channel region (20). Upon removal of the masking layer (16) source and drain regions (36, 38) are formed in the semiconductor substrate (10) and aligned to the gate electrode (34).

Abstract: The embodiments of the present invention allow the formation of interconnect and vias without forming via veils or excessive thinning of vias. Conductive members (52, 54, 56, 58) are formed with a pattern generally corresponding to the shape of interconnects. A lower intermetallic insulating layer (70)is deposited over the substrate (30) and removed over conductive members (52, 54, 56, 58) before forming via portions. Via portions are formed from the conductive members (52, 54, 56, 58). An upper intermetallic insulating layer (134) is formed and planarized to fill locations overlying the interconnect portions of the conductive members (52, 54, 56, 58) near the vias.

Abstract: A capacitor with a metal-oxide dielectric layer is formed with an upper electrode layer that is electrically connected to an underlying circuit element. The capacitor may be used in forming storage capacitors for DRAM and NVRAM cells. After forming an underlying circuit element, such as a source/drain region of a transistor, a metal-oxide capacitor is formed over the circuit element. An opening is formed through the capacitor and extends to the circuit element. An insulating spacer is formed, and a conductive member is formed that electrically connects the circuit element to the upper electrode layer of the metal-oxide capacitor. Devices including DRAM and NVRAM cells and methods of forming them are disclosed.

Abstract: An annealed amorphous silicon layer is formed prior to forming field isolation regions when using in a LOCOS field isolation process. The annealed amorphous silicon layer helps to reduce encroachment compared to conventional LOCOS field isolation process and helps to reduce the likelihood of forming pits within a substrate compared to a PBL field isolation process. The annealed amorphous silicon layer may be used in forming field isolation regions that defines the active regions between transistors including MOSFETs and bipolar transistors. Doped silicon or a silicon-rich silicon nitride layer may be used in place of conventional materials. The anneal of the amorphous silicon layer may be performed after forming a silicon nitride layer if the silicon nitride layer is deposited at a temperature no higher than 600 degrees Celsius.