Abstract: A semiconductor topography and a method for forming a drain extended metal oxide semiconductor (DEMOS) transistor is provided. The semiconductor topography includes at least a portion of an extended drain contact region formed within a well region and a plurality of dielectrically spaced extension regions interposed between the well region and a channel region underlying a gate structure of the topography. The channel region of a first conductivity type and the well region of a second conductivity type opposite of the first conductivity type. In addition, the plurality of dielectrically spaced extension regions and the extended drain contact region are of the second conductivity type. Each of the plurality of dielectrically spaced extension regions has a lower net concentration of electrically active impurities than the well region. Moreover, the extended drain contact region has a greater net concentration of electrically active impurities than the well region.

Abstract: An electrostatic discharge protection device for protecting a node includes a transistor, a silicon controlled rectifier, a second contact region laterally displaced from the first contact region, and a collection region adjacent the source region. The transistor includes a semiconductor substrate, a source region, a channel region adjacent the source region, a gate over the channel region, and a drain region laterally displaced from the channel. The silicon controlled rectifier includes the source region, a portion of the substrate, a doped well, and a first contact region in the well, laterally displaced from the drain region. The collection region, the source region and the gate, are metallically connected. The node, the first contact region, and the second contact region, are metallically connected, and the drain region is not metallically connected to the node.

Abstract: A method for fabricating a nonvolatile charge trap memory device is described. The method includes forming a first oxide layer on a surface of a substrate. The first oxide layer is exposed to a first decoupled plasma nitridation process having a first bias. Subsequently, a charge-trapping layer is formed on the first oxide layer. The charge-trapping layer is exposed to an oxidation process and then to a second decoupled plasma nitridation process having a second, different, bias.

Abstract: Devices for protecting drain extended metal oxide semiconductor (DEMOS) output transistors from damage caused by electrostatic discharge (ESD) events are provided. In general, the devices include a silicon controlled rectifier (SCR) and a DEMOS transistor configured to breakdown at a lower voltage than a breakdown voltage of the output driver transistor it is configured to protect. The devices further include a pair of ohmic regions configured to trigger the SCR upon breakdown of the drain contact region of the DEMOS transistor and a collection region configured to collect charge generated by the SCR. The transistor, the pair of ohmic regions, and the SCR are respectively configured and arranged to independently set the breakdown voltage of the drain contact region, the trigger voltage of the SCR, and the holding voltage of the SCR. One of the ohmic regions may be coupled to the drain contact region of the transistor.

Abstract: A circuit having a high voltage, drain-extended (DE) metal-oxide-semiconductor (MOS) transistor and method for fabricating the same are provided. Generally, the circuit includes an n-channel (NMOS) transistor having: (i) a source and drain formed in a substrate, the source separated from the drain by a channel; and (ii) a diffused deep n-well (DNW) formed by a long, high temperature drive-in step. The DNW forms a drain-extension region for the NMOS transistor surrounding the drain and extending a predetermined distance into the channel. The drain extension region has a doping concentration lower than the source and drain to deplete during reverse biasing of the transistor, thereby raising a breakdown voltage of the transistor. Preferably, the circuit further includes a DE p-channel MOS (PMOS) transistor in which the DNW forms a well tub for the PMOS transistor, and a p-well in DNW forms a DE region therefore. Other embodiments are also disclosed.

Abstract: A regulated circuit having a number of metal-oxide-semiconductor field effect transistors (MOS FETS) and a method for using the same are provided to reduce Negative Bias Temperature Instability degradation of the MOS FETs on the circuit. In one embodiment, the method involves steps of: (i) detecting degradation in performance of at least one of the MOS FETs causing a shift in threshold voltage (VT) of the MOS FET; and (ii) if the shift in VT exceeds a predetermined value, forward biasing the MOS FETS, thereby reducing or reversing the shift in VT. Optionally, the method includes an initial step of determining if the circuit is in a non-dynamic operating mode before-forward biasing the MOS FETS. Other embodiments are also disclosed.

Abstract: Methods for fabricating diffusion regions having steep concentration profiles within MOS devices while minimizing junction capacitance degradation are provided. In particular, methods are provided which include patterning a gate structure upon a semiconductor substrate and subsequently etching a recess in exposed portions of the substrate. In some cases, the method includes forming a first dopant region within the exposed portions prior to etching the recess. The method may additionally or alternatively include implanting a second set of dopants into portions of the semiconductor substrate bordering the recess. In either case, the method includes growing an epitaxial layer within the recess and implanting a third set of dopants into the semiconductor topography to form a second dopant region extending to a depth at least within the epitaxial layer.

Abstract: A method for fabricating a semiconducting device on a substrate, where the improvement includes forming a strained silicon germanium channel layer on the substrate. A gate insulation layer is formed on top of the strained silicon germanium channel layer, at a temperature that does not exceed about eight hundred centigrade. A gate electrode is formed on top of the gate insulation layer, and the gate electrode is patterned. A low dose drain dopant is impregnated into the substrate, and activated with a first laser anneal. A source-drain dopant is impregnated into the substrate, and activated with a second laser anneal. After the step of activating the low dose drain dopant with the first laser anneal, an insulating layer is formed around the gate electrode, at a temperature that does not exceed about eight hundred centigrade, and a spacer is formed around the gate electrode. The spacer is formed of a material that is reflective to the second laser anneal.

Abstract: Methods for fabricating diffusion regions having steep concentration profiles within MOS devices while minimizing junction capacitance degradation are provided. In particular, methods are provided which include patterning a gate structure upon a semiconductor substrate and subsequently etching a recess in exposed portions of the substrate. In some cases, the method includes forming a first dopant region within the exposed portions prior to etching the recess. The method may additionally or alternatively include implanting a second set of dopants into portions of the semiconductor substrate bordering the recess. In either case, the method includes growing an epitaxial layer within the recess and implanting a third set of dopants into the semiconductor topography to form a second dopant region extending to a depth at least within the epitaxial layer.

Abstract: A method of forming a narrow isolation structure in a semiconducting substrate. The isolation structure is a trench that has a bottom and sidewalls, and that is to be filled with an isolating material. The isolating material has desired electrical properties and desired chemical properties, and is substantially reactively grown from the semiconducting substrate. A precursor material layer is formed on the bottom of the trench and on the sidewalls of the trench. The precursor material layer has electrical properties and chemical properties that are substantially similar to the desired electrical properties and the desired chemical properties of the isolating material. A substantial portion of the precursor material layer is removed from the bottom of the trench to expose the semiconducting substrate at the bottom of the trench, while leaving a substantial portion of the precursor material layer on the sidewalls of the trench.

Abstract: A process for etching oxide is disclosed wherein a reproducibly accurate and uniform amount of silicon oxide can be removed from a surface of an oxide previously formed over a semiconductor substrate by exposing the oxide to a nitrogen plasma in an etch chamber while applying an rf bias to a substrate support on which the substrate is supported in the etch chamber. The thickness of the oxide removed in a given period of time may be changed by changing the amount of rf bias applied to the substrate through the substrate support.

Abstract: Provided are methods and composition for forming an isolation structure on an integrated circuit substrate. A trench is etched in the integrated circuit substrate. A light barrier layer is then formed in the trench such that the light barrier layer at least partially fills the trench to create an isolation structure, the light barrier layer being adapted for absorbing laser light applied during laser thermal processing, thereby preventing damage to the integrated circuit substrate. For instance, the light barrier layer may be a conductive layer such as polysilicon. A dielectric layer is then formed over the isolation structure. The dielectric layer may be adapted for transferring heat generated by the laser thermal processing to the light barrier layer. For instance, the dielectric layer may be formed through oxidation of a top surface of the light barrier layer.

Abstract: Provided is a process for forming a semiconductor device having salicided contacts. A concentration of metal is formed at the substrate surface by exposing the substrate to a metal plasma. The concentration of metal is then annealed to produce a salicided contact. In a separate embodiment, the metallization plasma and salicide anneal occur in-situ in one process step.

Abstract: A method of forming a narrow isolation structure in a semiconducting substrate. The isolation structure is a trench that has a bottom and sidewalls, and that is to be filled with an isolating material. The isolating material has desired electrical properties and desired chemical properties, and is substantially reactively grown from the semiconducting substrate. A precursor material layer is formed on the bottom of the trench and on the sidewalls of the trench. The precursor material layer has electrical properties and chemical properties that are substantially similar to the desired electrical properties and the desired chemical properties of the isolating material. A substantial portion of the precursor material layer is removed from the bottom of the trench to expose the semiconducting substrate at the bottom of the trench, while leaving a substantial portion of the precursor material layer on the sidewalls of the trench.

Abstract: A method of forming a narrow isolation structure in a semiconducting substrate. The isolation structure is a trench that has a bottom and sidewalls, and that is to be filled with an isolating material. The isolating material has desired electrical properties and desired chemical properties, and is substantially reactively grown from the semiconducting substrate. A precursor material layer is formed on the bottom of the trench and on the sidewalls of the trench. The precursor material layer has electrical properties and chemical properties that are substantially similar to the desired electrical properties and the desired chemical properties of the isolating material. A substantial portion of the precursor material layer is removed from the bottom of the trench to expose the semiconducting substrate at the bottom of the trench, while leaving a substantial portion of the precursor material layer on the sidewalls of the trench.

Abstract: A method of forming junctions in a semiconductor substrate, where a gate dielectric layer is grown on the semiconductor substrate, a gate electrode layer is deposited on the gate dielectric layer, and a sacrificial layer is formed on the gate electrode layer. The sacrificial layer is patterned with a material to cover portions of the sacrificial layer and expose portions of the sacrificial layer. The exposed portions of the sacrificial layer are etched to remove the exposed portions of the sacrificial layer and expose portions of the gate electrode layer. The exposed portions of the gate electrode layer are etched to expose portions of the gate dielectric layer and form a gate electrode having exposed vertical faces. The sacrificial layer and the exposed portions of the gate dielectric layer are impregnated with a first species that inhibits diffusion of oxygen through the sacrificial layer and the exposed portions of the gate dielectric layer.

Abstract: A method for fabricating a semiconducting device on a substrate, where the improvement includes forming a strained silicon germanium channel layer on the substrate. A gate insulation layer is formed on top of the strained silicon germanium channel layer, at a temperature that does not exceed about eight hundred centigrade. A gate electrode is formed on top of the gate insulation layer, and the gate electrode is patterned. A low dose drain dopant is impregnated into the substrate, and activated with a first laser anneal. A source-drain dopant is impregnated into the substrate, and activated with a second laser anneal. After the step of activating the low dose drain dopant with the first laser anneal, an insulating layer is formed around the gate electrode, at a temperature that does not exceed about eight hundred centigrade, and a spacer is formed around the gate electrode. The spacer is formed of a material that is reflective to the second laser anneal.

Abstract: A method for fabricating a semiconducting device on a substrate, where the improvement includes forming a strained silicon germanium channel layer on the substrate. A gate insulation layer is formed on top of the strained silicon germanium channel layer, at a temperature that does not exceed about eight hundred centigrade. A gate electrode is formed on top of the gate insulation layer, and the gate electrode is patterned. A low dose drain dopant is impregnated into the substrate, and activated with a first laser anneal. A source-drain dopant is impregnated into the substrate, and activated with a second laser anneal. After the step of activating the low dose drain dopant with the first laser anneal, an insulating layer is formed around the gate electrode, at a temperature that does not exceed about eight hundred centigrade, and a spacer is formed around the gate electrode. The spacer is formed of a material that is reflective to the second laser anneal.

Abstract: A method of forming junctions in a semiconductor substrate, where a gate dielectric layer is grown on the semiconductor substrate, a gate electrode layer is deposited on the gate dielectric layer, and a sacrificial layer is formed on the gate electrode layer. The sacrificial layer is patterned with a material to cover portions of the sacrificial layer and expose portions of the sacrificial layer. The exposed portions of the sacrificial layer are etched to remove the exposed portions of the sacrificial layer and expose portions of the gate electrode layer. The exposed portions of the gate electrode layer are etched to expose portions of the gate dielectric layer and form a gate electrode having exposed vertical faces. The sacrificial layer and the exposed portions of the gate dielectric layer are impregnated with a first species that inhibits diffusion of oxygen through the sacrificial layer and the exposed portions of the gate dielectric layer.

Abstract: In accordance with the invention a high-k gate dielectric is formed by the steps of first forming a silicon oxide layer over a silicon substrate and then exposing the silicon oxide to a flux of low energy plasma containing metal ions which, when inserted into silicon oxide, form a high-k dielectric material suitable for use as a high-k gate dielectric. In one embodiment, the silicon oxide is exposed to a first plasma containing a first species of metal ions and then to a plasma of another species of metal ions which, when inserted into the silicon oxide with the metal ions in the first plasma, further increase the dielectric constant of the silicon oxide.