Abstract: A method for forming a metal gate (20) structure begins by providing a semiconductor substrate (12). The semiconductor substrate (12) is cleaned to reduce trap sites. A nitrided layer (14) having a thickness of less than approximately 20 Angstroms is formed over the substrate (12). This nitrided layer prevents the formation of an oxide at the substrate interface and has a dielectric constant greater than 3.9. After the formation of the nitrided layer(14), a metal oxide layer (16) having a permittivity value of greater than roughly 8.0 is formed over the nitrided layer (14). A metal gate (20) is formed over the nitrided layer whereby the remaining composite gate dielectric (14 and 16) has a larger physical thickness but a high-performance equivalent oxide thickness (EOT).

Abstract: A nonvolatile memory architecture (10) contains a plurality of memory arrays (12) formed by a plurality of floating gate memory cells and supports a 1.times. and 2.times. architecture. The nonvolatile memory design contains high voltage row decoders (16), low voltage row decoders (18), data multiplexors (24) and low voltage control circuitry (22). The nonvolatile memory architecture (10) features a pipelined scheme with a 100 MHz operation. Data multiplexers (24) and sense amplifier circuitry (26) with a master/slave portion increase the data access rate.

Abstract: A method for forming CMOS transistors and ferroelectric capacitors on a single substrate (10) with improved yield begins by forming CMOS transistors (37a, 37b, 40, 42). A hydrogen anneal using 4-5% hydrogen and a remainder nitrogen is performed to reduce dangling atomic bonds at the gate dielectric/substrate interface of the transistors (37a, 37b, 40, 42). A silicon nitride layer (48) is then deposited over the transistors and on the backside of the wafer substrate (10) in order to substantially encapsulate the effects of the hydrogen anneal to the CMOS transistors (37a, 37b, 40, 42). Ferroelectric capacitor layers (54, 58, 60, 62, 64) are formed overlying the nitride layer (48) where the ferroelectric capacitor layers (54, 58, 60, 62, 64) are oxygen annealed in pure O.sub.2. The nitride layer (48) prevents the transistor hydrogen anneal from damaging the ferroelectric material by containing the hydrogen.

Abstract: A method for forming a tantalum-based anti-reflective coating (ARC) layer begins by forming an MOS metallic gate electrode layer (20) over a substrate (20). The MOS metallic gate electrode layer (20) is covered with an ARC layer (22). The ARC layer is preferably tantalum pentoxide or a tantalum pentoxide layer doped with one or more of nitrogen atoms and/or silicon atoms. The layers (22 and 20) are then selectively masked photoresist (24) that is selectively exposed to deep ultraviolet (DUV) radiation (28). The ARC layer (22) improves lithographic critical dimension (CD) control of the MOS metallic gate during exposure. The final MOS metallic gate is then patterned and etched using a fluorine-chlorine-fluorine time-progressed reactive ion etch (RIE) process, whereby metallic-gate MOS transistors are eventually formed.

Abstract: A method for forming a copper interconnect on an integrated circuit (IC) begins by forming a dielectric layer (20) having an opening. A tantalum-based barrier layer (21), such as TaN or TaSiN, is formed within the opening in the layer (20). A copper layer (22) is formed over the barrier layer (21). A first CMP process is used to polish the copper (22) to expose portions of the barrier (21). A second CMP process which is different from the first CMP process is then used to polish exposed portions of the layer (21) faster than the dielectric layer (20) or the copper layer (22). After this two-step CMP process, a copper interconnect having a tantalum-based barrier is formed across the integrated circuit substrate (12).

Abstract: A method for forming a contact structure (10) which enables the use of ultra-shallow source/drain junctions begins by forming source and drain regions (14) and gate electrode (16). The source and drain regions (14) and the gate electrode (16) are silicided to form silicide regions (20). A conductive tungsten nitride etch stop layer (22) is formed overlying the silicide regions (20). Contact plug regions (28) are then formed to contact to the etch stop layer (22) and silicided regions (20). At this point, all of the silicide regions (20) are electrically short circuited. To remove this electric short circuit, an isotropic etch process comprising hydrogen peroxide, ammonium hydroxide, and water is used to remove portions of the tungsten nitride regions which are between the individual contact portions (28) in a self-aligned manner.

Abstract: The time required to make test measurements across a large diameter wafer, such as a 300 mm wafer, is reduced by using a wafer measuring system that employs theta (.theta.) and radial (r) control instead of X-Y control. In one embodiment, a measurement arm (14) having a measurement head (16) is positioned over a wafer chuck (18) and a wafer (12) is placed onto the wafer chuck (18). The wafer (12) is then moved to one or more measuring points below the measurement head (16) via theta rotation (.theta.) and radial positioning. A measurement is then taken at the selected location.

Abstract: A passivation layer (16) is formed over a substrate (10) having an interconnect pad (12, 13). An opening in the passivation layer (16) exposes a portion of the interconnect pad (12, 13). A polyimide structure (18, 20) is formed adjacent to the opening in the passivation layer 16. Under bump metallurgy (22, 24) is formed over at least a portion of the polyimide structure (18, 20). A solder bump (28, 26) is formed over the Under bump metallurgy (22, 24).

Abstract: The present invention relates in general to a data processing system (10), and more particularly to a method and apparatus for providing instruction pipe (106) status information, including fullness information, external to data processing system (10). In one embodiment, an IPIPE2 integrated circuit terminal (15) is used to serially provide a pipe depth value indicating the fullness of the instruction pipe (106). The serial protocol used with the IPIPE2 (15) terminal includes a start bit, a fetch pointer value, and a plurality of idle bits. In one embodiment, IPIPE0 (13) and IPIPE1 (14) integrated circuit terminals may indicate loading and unloading of instruction pipe (106) and may stop toggling when central processing unit (102) is in a loop mode.

Abstract: The present disclosure is a method for in situ monitoring of backside contamination on a semiconductor wafer (120) between processing steps which are performed in a multi-chamber tool (500). In a first form, a laser source (220) and a detector (210) are mounted on a robotic arm (110, 111), or within a semiconductor processing tool (500). The laser (220) and detector (210) move along with the robotic arm (110) as the robotic arm (110) shuffles the wafer (120) between processing carriers (610-650) and chambers (510-540). While in transit the backside of the semiconductor wafer (120) is scanned by a laser beam (221), whereby contamination is detected by a detector (210). The laser (220) and detector (210) then scan the backside of the wafer (120) while the robotic arm (110) is in transit and/or while the robotic arm (110) is stationary in the processing sequence.

Abstract: A method for forming an integrated circuit involves forming trench isolation regions (208a) and a damascene gate electrode region (214) simultaneous with one another via overlapping process steps. By performing this simultaneous formation of a trench region (208a) and a damascene gate electrode (214) using a common dielectric layer (208), MOS integrated circuits can be formed with reduced processing steps while simultaneously avoiding adverse polysilicon stringers which are present in prior art damacene-formed gate electrode. A single dielectric layer (208) is deposited in order to provide trench fill material for a trench region (208a) while simultaneously providing the material needed for form an opening (210) which is used to define the dimensions and material content of a gate electrode (214).

Abstract: A method for forming a metal gate MOS transistor begins by forming source and drain electrodes (26, 28, and/or 118) within a substrate (12 or 102). These source and drain regions (26, 28, and 118) are self-aligned to a lithographically-patterned feature (24 or 108). After formation of the source and drain regions, the features (24 and 108 are processed to fill these features with a metallic gate layer (28a or 128a). This metal layer (28a or 128a) is then chemically mechanically polished (CMPed) to form a metallic plug region (28b or 128b) within the features (24 or 108). The plug region (28b or 128b) is formed in either an inlaid or dual inlaid manner wherein this metallic plug region (28b or 128b) is self-aligned to the previously formed source and drain regions and preferably functions as a metal MOS gate region.

Abstract: A test structure and test methodology are taught herein wherein a test structure (10) is used to test an entire integrated circuit product wafer (44). The test structure (10) has a backing support wafer (39). A die attach compound (38) is used to attach a plurality of segmented individual test integrated circuits 28-34 to the backing support wafer (39). The plurality of test integrated circuits 28-34 have a top conductive bump layer (26). This conductive bump layer (26) is contacted to a thin film signal distribution layer (14) which contains conductive interconnects, conductive layers, and dielectric layers which route electrical signals as illustrated in FIG. 2. The layer 14 also conductively connects to bumps (46) on a product wafer (44). In addition, leads (40) are coupled to conductive elements of the layer (14).

Abstract: A method for forming a dual gate oxide (DGO) structure begins by forming a first oxide layer (106) within active areas (110) and (112). A protection layer (108a) is then formed over the layer (106). A mask (114) is used to allow removal of the layers (106 and 108a) from the active area (110). A thermal oxidation process is then used to form a thin second oxide layer (118) within an active area (110). Conductive gate electrodes (120a and 120b) are then formed wherein the first oxide layer (106) and the protection layer (108c) are incorporated into the gate dielectric layer of an MOS transistor (122a). The transistor (122b) has a thinner gate oxide layer that excludes the protection layer (108c).

Abstract: A memory circuit and method of formation uses a transmission gate (24) as a select gate. The transmission gate (24) contains a transistor (30) which is an N-channel transistor and a transistor (28) which is a P-channel transistor. The transistors (28 and 30) are electrically connected in parallel. The use of the transmission gate (24) as a select gate allows reads and writes to occur to a memory cell storage device (i.e. a capacitor (32), a floating gate (22), etc.) without a significant voltage drop occurring across the transmission gate. In addition, EEPROM technology is more compatible with EPROM/flash technology when using a transmission gate as a select gate within EEPROM devices.

Abstract: A method for reducing particles (235) during a semiconductor process. A semiconductor substrate (230) is placed into a processing chamber (210). A processing pressure (108) is applied within the chamber (212). A processing power (102) is applied to the chamber. A grid power (104,106) for removing particles (235) is applied to the chamber (212). The processing power (102) is removed. The grid power (106) is removed after the processing power (102).

Abstract: A method of manufacturing a semiconductor component with a multi-level interconnect system includes providing a substrate (11), fabricating a device (12) in the substrate (11), forming an interconnect layer (15) over the substrate (11), depositing a dielectric layer (20) over the interconnect layer (15), depositing a separate interconnect layer (21) over the dielectric layer (20), etching a via (31) in the separate interconnect layer (21) and in the dielectric layer (20), and depositing a different interconnect layer (40) over the separate interconnect layer (21) and in the via (31) wherein the another interconnect layer (40) electrically couples the interconnect layer (15) and the separate interconnect layer (21).

Abstract: A method and apparatus for detecting copper (Cu) contamination on the backside of a wafer (120) begins by providing the wafer (120). The wafer (120) is rotated about a rotational axis via a motor/computer controlled wafer stage (118). In addition to rotation of the wafer (120), motor/computer control of a monochromator (116) is used to raster scan an X-ray beam (114b) across a surface of the rotating wafer (120). A plurality of X-ray detectors (122) are arrayed in one or more rows in close proximity to the scanned surface of the semiconductor wafer (120). The detectors (122), detect X-ray fluorescence emission from the surface of the wafer (120) whereby copper contamination of the wafer (120) can be determined in an accurate and time efficient manner which enables contamination detection in-line with normal wafer processing.

Abstract: In a Plug and Play environment different kinds of EEPROMs can be used having different access protocols without having to add an additional pin to the EEPROM to indicate its type. The first type of EEPROM has a code which indicates the first type stored on a predetermined address whereas the second type of EEPROM having a different read protocol has another code which indicates the second type stored on a consecutive address. When the Plug and Play controller accesses the EEPROM for a read either the code 1 or code 2 is outputted whereby the appropriate read protocol is identified.

Abstract: When a processor (102) issues a request for an address (502), a determination is made as to whether or not the address is contained within a buffer (103) or cache associated with the processor (102), or the address is contained within a line of data currently being fetched from an external memory system (105). If the address is not contained within the buffer or cache and is not contained within a line being currently fetched, the current fetch will be cancelled (515, 516).