Abstract: In accordance with some embodiments described herein, a system for processing substrates includes two or more process modules, a substrate handling robot, a load lock chamber, and a transverse substrate handler. The transverse substrate handler includes mobile transverse chambers configured to convey substrates to process modules, wherein each mobile transverse chamber is configured to maintain a specified gas condition during the conveyance of the substrates. The transverse substrate handler further includes a rail for supporting the mobile transverse chambers, wherein the rail is positioned adjacent to entry of the process modules, and drive systems for moving the mobile transverse chambers on the rail.

Abstract: An antifuse structure includes a first electrode, a layer of enhanced amorphous silicon over the first electrode, and a second electrode over the layer of enhanced amorphous silicon. The layer of enhanced amorphous silicon is formed by an ion-implantation of a neutral species and a dopant species into a deposited layer of amorphous silicon, such that the antifuse structure will have a stable conductive link in a programmed state and such that it will be less susceptible to off-state leakage in an unprogrammed state. A method for making an antifuse structure includes forming a lower electrode, depositing an amorphous silicon layer over the lower electrode, ion-implanting a neutral species and a dopant species into the amorphous silicon layer, and forming an upper electrode over the amorphous silicon layer.

Abstract: A method for substantially reducing variations in a programming voltage of an anti-fuse structure formed on an integrated circuit wafer. The anti-fuse structure has a metal-one layer, an anti-fuse layer disposed above the metal-one layer, a oxide layer disposed above the anti-fuse layer, and a via hole in the oxide layer through to the anti-fuse layer for receiving a deposition of a metal-two material. The method includes the step of rendering a selected anti-fuse area susceptible to fuse link formation by reducing a resistivity of the selected anti-fuse area to diffusion of atoms from one of the metal-one layer and the metal-two layer when a programming voltage is applied between the metal one layer and the metal two layer. The selected anti-fuse area is located in the anti-fuse layer and substantially adjacent to and outside of an anti-fuse area directly below the via hole. The method further includes the step of depositing the metal-two material into the via hole.

Abstract: A computer-aided method and system are provided for obtaining a measurement of the capacitance value of a device under test (DUT). The complex impedance of a device under test (DUT) is measured at two nearby frequencies using an RLC meter. The two complex impedance values are then stored in a computer readable medium. The DUT is modeled by a programmed computer as a four element RLC model circuit including a resistor and inductor in series with a parallel RC circuit having a single capacitor which represents the capacitance of the DUT. Four equations which describe the electrical characteristics of the four element RLC model circuit are stored in a computer readable medium. The four measured values of complex impedance are substituted by the computer into the four stored equations. Values are obtained for the four individual RLC circuit elements by solving the four equations. The four unknown values are obtained by use of an optimization routine and then stored to a computer readable medium.

Abstract: An integrated circuit having a semiconductor substrate and an anti-fuse structure formed on the semiconductor substrate. The anti-fuse structure includes a metal-one layer and an anti-fuse layer disposed above the metal-one layer. The anti-fuse layer has a first resistance value when the anti-fuse structure is unprogrammed and a second resistance value lower than the first resistance value when the anti-fuse structure is programmed. There is further provided an etch stop layer disposed above the anti-fuse layer, and an inter-metal oxide layer disposed above the etch stop layer with the inter-metal oxide layer has a via formed therein. Additionally, there is further provided a metal-two layer disposed above the inter-metal oxide layer. In this structure, a portion of the metal-two layer is in electrical contact with the anti-fuse layer through the via in the inter-metal oxide layer.

Abstract: An antifuse structure includes a first electrode, a layer of enhanced amorphous silicon over the first electrode, and a second electrode over the layer of enhanced amorphous silicon. The layer of enhanced amorphous silicon is formed by an ion-implantation of a neutral species and a dopant species into a deposited layer of amorphous silicon, such that the antifuse structure will have a stable conductive link in a programmed state and such that it will be less susceptible to off-state leakage in an unprogrammed state. A method for making an antifuse structure includes forming a lower electrode, depositing an amorphous silicon layer over the lower electrode, ion-implanting a neutral species and a dopant species into the amorphous silicon layer, and forming an upper electrode over the amorphous silicon layer.

Abstract: The use of a test chip having a wide channel MOSFETs of different channel widths and effective gate lengths allows for an experimental determination of the fringe capacitance per unit width. The use of channel widths greater than 100 microns increases the accuracy of the measured capacitance values.

Abstract: A technique for forming a high-performance sub-half micron MOS transistor is disclosed which has improved short channel characteristics without degradation of device performance. The transistor comprises a semiconductor substrate, a gate electrode, graded source and drain impurity regions, a first set of gate sidewall spacers, and a second set of gate sidewall spacers. The graded source and drain impurity regions comprise a relatively linear continuum of doped regions, ranging from lightly doped (LDD) regions, to moderately doped (MDD) regions, to heavily doped regions. Additionally, the transistor may include a punch through barrier region located within the substrate under the gate electrode. With these features, the transistor of the present invention allows for more precise control of conduction channel length without degradation of either (1) body factor and current drive, and/or (2) junction leakage, and without compromising hot carrier immunity.

Abstract: Disclosed is a method for programming an antifuse structure. The antifuse structure is programmed by applying an alternating current having alternating current pulses between a bottom and a top electrode to generate a conduction path through an antifuse material sandwiched between the electrodes. The conduction path is formed incrementally due to an electron flow produced as a result of each alternating current pulse thereby defining the conduction path at a substantially centered portion of the antifuse material.

Abstract: A system and method for reducing the contact resistance associated with tungsten plug contacts to P-doped diffusion regions of a semiconductor device. Before or during the formation of the tungsten plug contacts, a high energy, low dosage of an N-dopant or neutral species such as silicon or germanium is implanted into the P-doped diffusion regions of the semiconductor device. The implantation causes lattice damage within the P-doped diffusion regions, enhancing diffusion of the P-dopant within the P-doped diffusion regions. This results in the P-dopant diffusing toward the contact, replacing dopant lost to segregation into the contact metalization, and thus reducing the contact resistance.

Abstract: A transistor is formed which has improved hot carrier immunity. On a substrate, between two source/drain regions, a gate region is formed over a dielectric region. An implant is used to dope the source/drain regions. After doping the source/drain regions, a tilted angle nitrogen implant is performed to implant nitrogen into areas of the dielectric region overlaying the drain/source regions of the transistor. The tilted angle nitrogen implant may be performed before or after forming spacer regions on sides of the gate region.

Abstract: A bipolar transistor is fabricated in a CMOS-compatible process so as to be self-aligning, with resultant small geometry and improved high frequency performance, and to have improved hot carrier characteristics. The bipolar device has a laterally graded emitter structure that is fabricated in a "top-down" implant process. During fabrication sidewall spacers are formed overlying the peripheral region of the laterally graded emitter. These spacers protect the underlying region against counter-doping during a subsequent intrinsic base implant, and cause the emitter and base contacts to be self-aligning. Because bipolar dimensions are thus reduced, a very narrow base width is achieved, resulting in improved device cutoff frequency. Further, a narrower emitter-base contact separation is achieved, reducing junction area and attendant junction capacitance. A base link region is formed to further improve emitter-base breakdown voltage, and to reduce extrinsic base resistance.

Abstract: A bipolar transistor is fabricated in a CMOS-compatible process with a laterally graded emitter structure that is fabricated in a "top-down" implant process. The laterally graded emitter decreases electric field intensities in the emitter-base junction under reverse bias, thus reducing hot carrier generation and improving emitter-base junction breakdown voltage. High current gain is further maintained by establishing sharply defined emitter-base junctions. During fabrication a blocking layer and overlying cap layer are formed in an inverted "T" shape over a desired emitter window region. Lateral projection of the cap ledges are used to define the laterally graded emitter width, while the distance separating the cap ledges defines the width of the central emitter region. The central emitter region is implanted and driven-in to a desired depth, after which the protective cap is removed.