Abstract: A semiconductor device and manufacturing process therefor is provided in which angled dopant implantation is followed by the formation of vertical trenches in the silicon on insulator substrate adjacent to the sides of the semiconductor gate. A second dopant implantation in the exposed the source/drain junctions is followed by a rapid thermal anneal that forms the semiconductor channel in the substrate. Contacts having inwardly curved cross-sectional widths in the semiconductor substrate are then formed which connect vertically to the exposed source/drain junctions either directly or through salicided contact areas.

Abstract: A semiconductor device and manufacturing process therefor is provided in which angled dopant implantation is followed by the formation of vertical trenches in the silicon on insulator substrate adjacent to the sides of the semiconductor gate. A second dopant implantation in the exposed the source/drain junctions is followed by a rapid thermal anneal that forms the semiconductor channel in the substrate. Contacts having inwardly curved cross-sectional widths in the semiconductor substrate are then formed which connect vertically to the exposed source/drain junctions either directly or through salicided contact areas.

Abstract: A process for fabricating a MOSFET device, featuring source/drain extension regions, formed after the utilization of high temperature processes, such as heavily doped source/drain regions, has been developed. Disposable insulator spacers are formed on the sides of doped, SEG silicon regions, followed formation of a gate insulator layer, and an overlying gate structure, on a region of the semiconductor substrate located between the doped SEG silicon regions. The temperature experienced during these process steps result in the formation of the heavily doped source/drain, underlying the SEG silicon regions. Selective removal of the disposable spacers, allows the source/drain extension regions to be placed in the space vacated by the disposable spacers, adjacent to the heavily doped source/drain region. Insulator spacers are then used to fill the spaces vacated by removal of the disposable spacers, directly overlying the source/drain extension regions.

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 new method for forming a silicon-on-insulator MOSFET while eliminating floating body effects is described. A silicon-on-insulator substrate is provided comprising a silicon semiconductor substrate underlying an oxide layer underlying a silicon layer. A first trench is etched partially through the silicon layer and not to the underlying oxide layer. Second trenches are etched fully through the silicon layer to the underlying oxide layer wherein the second trenches separate active areas of the semiconductor substrate and wherein one of the first trenches lies within each of the active areas. The first and second trenches are filled with an insulating layer. Gate electrodes and associated source and drain regions are formed in and on the silicon layer in each active area. 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 new process for fabricating an alternating phase-shifting photomask having an alignment monitor is described. An opaque layer is provided overlying a substrate. The opaque layer is patterned to provide a mask pattern. A phase-shifting pattern is formed on the substrate wherein a portion of the phase-shifting pattern comprises an alignment monitor whereby alignment between the mask pattern and the phase-shifting pattern can be tested.

Abstract: A triple layered low dielectric constant material dual damascene metallization process is described. Metal lines are provided covered by an insulating layer overlying a semiconductor substrate. A first dielectric layer of a first type is deposited overlying the insulating layer. A second dielectric layer of a second type is deposited overlying the first dielectric layer. A via pattern is etched into the second dielectric layer. Thereafter, a third dielectric layer of the first type is deposited overlying the patterned second dielectric layer. Simultaneously, a trench pattern is etched into the third dielectric layer and the via pattern is etched into the first dielectric layer to complete the formation of dual damascene openings in the fabrication of an integrated circuit device. If the first type is a low dielectric constant organic material, the second type will be a low dielectric constant inorganic material.

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 for forming an electrostatic discharge device using silicon-on-insulator technology is described. A silicon-on-insulator substrate is provided comprising a semiconductor substrate underlying an oxide layer underlying a silicon layer. The silicon layer and oxide layer are patterned to form a gate electrode wherein the semiconductor substrate is exposed. Ions are implanted into the exposed semiconductor substrate to form source and drain regions adjacent to the gate electrode. Spacers are formed on sidewalls of the gate electrode. An interlevel dielectric layer is deposited overlying the gate electrode. Openings are formed through the interlevel dielectric layer to the source and drain regions and filled with a conducting layer. The conducting layer is patterned to form conducting lines to complete formation of an electrostatic discharge device using SOI technology in the fabrication of integrated circuits.

Abstract: A semiconductor device and manufacturing process therefor is provided in which angled dopant implantation is followed by the formation of vertical trenches in the silicon on insulator substrate adjacent to the sides of the semiconductor gate. A second dopant implantation in the exposed the source/drain junctions is followed by a rapid thermal anneal which forms the semiconductor channel in the substrate. Contacts are then formed which connect vertically to the exposed source/drain junctions either directly or through salicided contact areas.

Abstract: A process for fabricating a MOSFET device, featuring source/drain extension regions, formed after the utilization of high temperature processes, such as heavily doped source/drain regions, has been developed. Disposable insulator spacers are formed on the sides of doped, SEG silicon regions, followed formation of a gate insulator layer, and an overlying gate structure, on a region of the semiconductor substrate located between the doped SEG silicon regions. The temperature experienced during these process steps result in the formation of the heavily doped source/drain, underlying the SEG silicon regions. Selective removal of the disposable spacers, allows the source/drain extension regions to be placed in the space vacated by the disposable spacers, adjacent to the heavily doped source/drain region. Insulator spacers are then used to fill the spaces vacated by removal of the disposable spacers, directly overlying the source/drain extension regions.

Abstract: A method of patterning a hard mask, the comprising the following steps. A semiconductor structure is provided. A conductor film is formed over the semiconductor structure. An oxide layer is formed over the conductor film. A patterned metal oxide layer is formed over the conductor film. The oxide layer and the conductor film are etched, using the metal oxide layer as a hard mask, to form a patterned structure.

Abstract: An integrated microelectronics semiconductor circuit fabricated on a silicon-on-insulator (SOI) type substrate can be protected from unwanted current surges and excessive heat buildup during fabrication by means of a heat-dissipating, protective plasma-induced-damage (PID) diode. The present invention fabricates such a protective diode as a part of the overall scheme in which the transistor devices are formed.

Abstract: A process for fabricating a MOSFET device, featuring source/drain extension regions, formed after the utilization of high temperature processes, such as heavily doped source/drain regions, has been developed. Disposable insulator spacers are formed on the sides of doped, SEG silicon regions, followed formation of a gate insulator layer, and an overlying gate structure, on a region of the semiconductor substrate located between the doped SEG silicon regions. The temperature experienced during these process steps result in the formation of the heavily doped source/drain, underlying the SEG silicon regions. Selective removal of the disposable spacers, allows the source/drain extension regions to be placed in the space vacated by the disposable spacers, adjacent to the heavily doped source/drain region. Insulator spacers are then used to fill the spaces vacated by removal of the disposable spacers, directly overlying the source/drain extension regions.

Abstract: A process for fabricating a MOSFET device, featuring source/drain extension regions, formed after the utilization of high temperature processes, such as heavily doped source/drain regions, has been developed. Disposable insulator spacers are formed on the sides of doped, SEG silicon regions, followed formation of a gate insulator layer, and an overlying gate structure, on a region of the semiconductor substrate located between the doped SEG silicon regions. The temperature experienced during these process steps result in the formation of the heavily doped source/drain, underlying the SEG silicon regions. Selective removal of the disposable spacers, allows the source/drain extension regions to be placed in the space vacated by the disposable spacers, adjacent to the heavily doped source/drain region. Insulator spacers are then used to fill the spaces vacated by removal of the disposable spacers, directly overlying the source/drain extension regions.

Abstract: A method for forming a novel thick oxide electrostatic discharge device using shallow trench isolation technology is described. A trench is etched into a semiconductor substrate. An oxide layer is deposited overlying the semiconductor substrate and filling the trench. The oxide within the trench is partially etched away leaving the oxide on the sidewalls and bottom of the trench. The oxide is polished away to the surface of the semiconductor substrate whereby oxide remains only on the sidewalls and bottom of the trench. A gate is formed within the trench whereby the gate is surrounded by the oxide. First ions are implanted into the semiconductor substrate adjacent to the trench to form N-wells. Second ions are implanted into the semiconductor substrate in a top portion of the N-wells to form source/drain regions. Third ions are implanted into the semiconductor substrate underlying the N-wells and underlying the trench to form electrostatic discharge trigger taps.

Abstract: An integrated microelectronics semiconductor circuit fabricated on a silicon-on-insulator (SOI) type substrate can be protected from unwanted current surges and excessive heat buildup during fabrication by means of a heat-dissipating, protective plasma-induced-damage (PID) diode. The present invention fabricates such a protective diode as a part of the overall scheme in which the transistor devices are formed.

Abstract: A new method of fabricating a sub-quarter micron MOSFET device is achieved. A semiconductor substrate is provided. Isolation regions are formed in this substrate. An oxide layer is provided overlying both the substrate and the isolation regions. The oxide layer is patterned and etched exposing two regions of the substrate. A selective epitaxial growth (SEG) is performed with in situ doping covering the two exposed substrate regions formed during the previous step. The doped SEG regions will form the source and drain contact regions of the MOSFET. The oxide layer region between the two doped SEG regions is then patterned and etched away exposing the substrate. This is followed by a gate oxide formation and either a polysilicon or metal gate deposition. Planarization is then performed on the surface to facilitate interconnection later in the process and to form the final gate structure.

Abstract: A transient protection circuit is described which provides electrostatic discharge (ESD) protection for an internal circuit of an IC. The transient protection circuit comprises two Zener diodes connected in series between the input pad and the internal circuit of the IC. A sufficiently large ESD pulse will drive one the two Zener diodes into breakdown mode, thereby reducing the magnitude of the ESD pulse to the remainder of the circuit. Resistive means are paralleled with the Zener diodes to provide a signal path at non-ESD voltages. To help shunt the ESD current away from the internal circuit, PMOS and NMOS transistors are connected in parallel between the positive and the negative voltage supply and their junction is connected to the internal circuit. Negative ESD pulses cause the PMOS transistors to turn on, dumping the ESD energy into the positive voltage supply, while positive ESD pulses cause the NMOS transistors to turn on, dumping the ESD energy into the negative voltage supply.

Abstract: A method for fabricating a metal-oxide-metal capacitor is described. A first insulating layer is provided overlying a semiconductor substrate. A barrier metal layer and a first metal layer are deposited over the insulating layer. A titanium layer is deposited overlying the first metal layer. The titanium layer is exposed to an oxidizing plasma while simultaneously a portion of the titanium layer where the metal-oxide-metal capacitor is to be formed is exposed to light whereby the portion of the titanium layer exposed to light reacts with the oxidizing plasma to form titanium oxide. Thereafter, the titanium layer is removed, leaving the titanium oxide layer where the metal-oxide-metal capacitor is to be formed. A second metal layer is deposited overlying the first metal layer and the titanium oxide layer.