Abstract: Semiconductor devices and fabrication methods are provided, in which metal transistor gates are provided for MOS transistors. Metal nitride is formed above a gate dielectric. A lanthaide series metal is implanted into the metal screen layer above the gate dielectric. The lanthaide metal is contained in the screen layer or at the interface between the screen metal layer and the gate dielectric. This process provides adjustment of the gate electrode work function, thereby tuning the threshold voltage of the resulting PMOS or NMOS transistors.

Abstract: In accordance with various embodiments, semiconductor devices and methods of forming semiconductor devices having non-rectangular active regions are provided. An exemplary method includes using a first mask to form a plurality of first features over a non-rectangular shaped active region and at least one ghost feature, wherein the plurality of first features extend beyond an edge of the non-rectangular shaped active region. The method further includes using a second mask to remove a portion of the plurality of first features extending beyond the edge of the non-rectangular shaped active region and the at least one ghost feature.

Abstract: Methods and apparatus for rendering plural channels on a common display are provided. In a method embodiment, a method for allowing sharing of a display by a plurality of users wishing to view a plurality of respective images includes displaying the plurality of respective images sequentially on the display. The method further includes selectively allowing the respective image to be viewed by the respective user, but not by any other of the plurality of users.

Abstract: The present invention provides a method of manufacturing a metal silicide electrode (100) for a semiconductor device (110). The method comprises depositing by physical vapor deposition, germanium atoms (120) and transition metal atoms (130) to form a metal-germanium alloy layer (140) on a semiconductor substrate (150). The metal-germanium alloy layer and the semiconductor substrate are reacted to form a metal silicide electrode. Other aspects of the present invention include a method of manufacturing an integrated circuit (400).

Abstract: A method for manufacturing a semiconductor device. The method comprises forming a dielectric layer. Forming the dielectric layer includes depositing a silicon oxide layer on a semiconductor substrate, nitridating the silicon oxide layer to form a nitrided silicon oxide layer and incorporating lanthanide atoms into the nitrided silicon oxide layer to form a lanthanide silicon oxynitride layer.

Abstract: The present invention provides a method for manufacturing a semiconductor device. The method, in one embodiment, includes forming a silicon oxide masking layer over a substrate in a first active region and a second active region of a semiconductor device, patterning the silicon oxide masking layer to expose the substrate in the first active region. The method further includes forming a layer of dielectric material over the substrate in the first active region, the patterned silicon oxide masking layer protecting the substrate from the layer of dielectric material in the second active region.

Abstract: The present invention provides method of forming a gate dielectric that includes forming a metal source layer (210) comprising a metal and at least one nonmetallic element over a substrate (110). The metal source layer (210) is formed having a composition rich in the metal. A dielectric layer (310) comprising the metal is formed over the metal source layer (210).

Abstract: A method is disclosed for implanting and activating antimony as a dopant in a semiconductor substrate. A method is also disclosed for implanting and activating antimony to form a source/drain extension region in the formation of a transistor, in such a manner as to achieve high activation and avoid deactivation via subsequent exposure to high temperatures. This technique facilitates the formation of very thin source/drain regions that exhibit reduced sheet resistance while also suppressing short channel effects. Enhancements to these techniques are also suggested for more precise implantation of antimony to create a shallower source/drain extension, and to ensure formation of the source/drain extension region to underlap the gate. Also disclosed are transistors and other semiconductor components that include doped regions comprising activated antimony, such as those formed according to the disclosed methods.

Abstract: Methods are disclosed for forming an SRAM cell having symmetrically implanted active regions and reduced cross-diffusion therein. One method comprises patterning a resist layer overlying a semiconductor substrate to form resist structures about symmetrically located on opposite sides of active regions of the cell, implanting one or more dopant species using a first implant using the resist structures as an implant mask, rotating the semiconductor substrate relative to the first implant by about 180 degrees, and implanting one or more dopant species into the semiconductor substrate with a second implant using the resist structures as an implant mask. A method of performing a symmetric angle implant is also disclosed to provide reduced cross-diffusion within the cell, comprising patterning equally spaced resist structures on opposite sides of the active regions of the cell to equally shadow laterally opposed first and second angled implants.

Abstract: One aspect of the invention provides a semiconductor device that includes gate electrodes comprising a metal or metal alloy located over a semiconductor substrate, wherein the gate electrodes are free of spacer sidewalls. The device further includes source/drains having source/drain extensions associated therewith, located in the semiconductor substrate and adjacent each of the gate electrodes. A first pre-metal dielectric layer is located on the sidewalls of the gate electrodes and over the source/drains, and a second pre-metal dielectric layer is located on the first pre-metal dielectric layer. Contact plugs extend through the first and second pre-metal dielectric layers.

Abstract: A field emission device 100 comprises an anode 105 and a cathode 110 separated by a distance 115 from the anode. At least one of the anode or cathode is configured to move with respect to the other in response to an applied voltage 120 to at least one of the anode and cathode, the distance being adjustable by the movement.

Abstract: A 2-terminal (i.e., anode, cathode) symmetrical bi-directional semiconductor electrostatic discharge (ESD) protection device is disclosed. The symmetrical bi-directional semiconductor ESD protection device design comprises a first and second shallow wells symmetrically spaced apart from a central floating well. Respective shallow wells comprise a first and second highly doped contact implant with opposite doping types (e.g., n-type, p-type). One or more field plates, connected to the central floating well, extend laterally outward from above the central well. The device can be used as an ESD protection device at a bi-directional I/O (e.g., in parallel with a symmetrical MOS to be protected). Upon an ESD event at an input node comprising the first and second shallow wells, a coupled npn-pnp bipolar component comprising the center well, the first and second shallow wells, and the first and second contact implants, is triggered, thereby shunting current from the first to the second shallow well.

Abstract: A method for fabricating a CMOS integrated circuit (IC) includes providing a substrate having a semiconductor surface, wherein the semiconductor surface has PMOS regions for PMOS devices and NMOS regions for NMOS devices. A gate dielectric layer is formed on the semiconductor surface followed by forming at least a first metal including layer on the gate dielectric layer. A polysilicon or amorphous silicon layer is formed on the first metal including layer to form an intermediate gate electrode stack. A masking pattern is formed on the intermediate gate electrode stack. The polysilicon or amorphous silicon layer is dry etched using the masking pattern to define a patterned intermediate gate electrode stack over the NMOS or PMOS regions, wherein the dry etching stops on a portion of the first metal comprising layer. The masking pattern is removed using a first post etch clean for stripping the masking pattern.

Abstract: Source and drain regions are formed in a first-type semiconductor device. Then, a high tensile stress capping layer is formed over the source and drain regions. A thermal process is then performed to re-crystallize the source and drain regions and to introduce tensile strain into the source and drain regions of the first-type semiconductor device. Afterwards, source and drain regions are formed in a second-type semiconductor device. Then, a high compressive stress capping layer is formed over the source and drain regions of the second-type semiconductor device. A thermal process is performed to re-crystallize the source and drain regions and to introduce compressive strain into the source and drain regions of the second-type semiconductor device.

Abstract: Semiconductor devices and fabrication methods are provided in which disposable gates are formed over isolation regions. Sidewall structures, including disposable sidewall structures, are formed on sidewalls of the disposable gates. An epitaxially grown silicon germanium is formed in recesses defined by the sidewalls. The process provides a compressive strained channel in the device without faceting of the epitaxially grown silicon germanium.

Abstract: A test circuit for, and method of, determining electrical properties of an underlying interconnect layer and an overlying interconnect layer of an integrated circuit (IC) and an IC incorporating the test circuit or the method. In one embodiment, the test circuit includes a gate chain having a ring path and a stage. In one embodiment, the stage includes: (1) a underlying test segment in the underlying interconnect layer, (2) a overlying test segment in the overlying interconnect layer and (3) logic circuitry activatible after formation of the underlying interconnect layer and before formation of the overlying interconnect layer to place the underlying test segment in the ring path and further activatible after the formation of the overlying interconnect layer to substitute the overlying test segment for the underlying test segment in the ring path.

Abstract: A method for forming a bipolar transistor device includes providing a semiconductor substrate. An oxide layer is formed on the semiconductor substrate. The oxide layer is patterned to form an opening that exposes a portion of the semiconductor substrate. A dopant, such as antimony, is implanted into the semiconductor substrate through the opening to form a buried layer. An upper portion of the mask layer is removed to define a thin mask layer. A buried layer diffusion process is performed to drive in the implanted dopants while mitigating recess formation.

Abstract: A test structure which can be used to detect residual conductive material such as polysilicon which can result from an under etch comprises a PMOS transistor and an OTP EPROM floating gate device. By testing the devices using different testing parameters, it can be determined whether residual conductive material remains subsequent to an etch, and where the residual conductive material is located on the device. A method for testing a semiconductor device using the test structure is also described.

Abstract: A wafer transfer machine transfers wafers from either of a first wafer cassette (55) and a second wafer cassette (56) having incompatible registration features into the other, and includes a support plate (30) having a top surface (38) for supporting the first and second wafer cassette. A first and second registration bosses attached to the top surface extend upward into registration features of the first and second wafer cassette, respectively. A carriage (1) is supported by and movable in opposite directions along a track mechanism (41A,B) that is attached in fixed relationship to the support plate (30). First and second wafer pushing members (10A,B) are supported by the carriage. Each wafer pushing member can be moved to push wafers in one of the wafer cassettes into the other by moving the carriage in one direction or the other.

Abstract: A method of fabricating an integrated BiCMOS circuit is provided, the circuit including bipolar transistors 10 and CMOS transistors 12 on a substrate. The method comprises the step of forming an epitaxial layer 28 to form a channel region of a MOS transistor and a base region of a bipolar transistor. Growing of the epitaxial layer includes growing a first sublayer of silicon 28a, a first sublayer of silicon-germanium 28b onto the first sublayer of silicon, a second sublayer of silicon 28c onto the first sublayer of silicon-germanium, and a second sublayer of silicon-germanium 28d onto the second sublayer of silicon. Furthermore, an integrated BiCMOS circuit is provided, which includes an epitaxial layer 28 as described above.