Abstract: A method includes forming a non-continuous epitaxial layer over a semiconductor substrate. The substrate includes multiple mesas separated by trenches. The epitaxial layer includes crystalline Group III nitride portions over at least the mesas of the substrate. The method also includes depositing a dielectric material in the trenches. The method could also include forming spacers on sidewalls of the mesas and trenches or forming a mask over the substrate that is open at tops of the mesas. The epitaxial layer could also include Group III nitride portions at bottoms of the trenches. The method could further include forming gate structures, source and drain contacts, conductive interconnects, and conductive plugs over at least one crystalline Group III nitride portion, where at least some interconnects and plugs are at least partially over the trenches. The gate structures, source and drain contacts, interconnects, and plugs could be formed using standard silicon processing tools.

Abstract: A method includes forming a non-continuous epitaxial layer over a semiconductor substrate. The substrate includes multiple mesas separated by trenches. The epitaxial layer includes crystalline Group III nitride portions over at least the mesas of the substrate. The method also includes depositing a dielectric material in the trenches. The method could also include forming spacers on sidewalls of the mesas and trenches or forming a mask over the substrate that is open at tops of the mesas. The epitaxial layer could also include Group III nitride portions at bottoms of the trenches. The method could further include forming gate structures, source and drain contacts, conductive interconnects, and conductive plugs over at least one crystalline Group III nitride portion, where at least some interconnects and plugs are at least partially over the trenches. The gate structures, source and drain contacts, interconnects, and plugs could be formed using standard silicon processing tools.

Abstract: The present invention provides a narrow/short high performance MOS device structure that includes a rectangular-shaped semiconductor substrate region having a first conductivity type. A region of dielectric material is formed at the center of the substrate region. Four substrate diffusion regions, each having a second conductivity type opposite the first conductivity type, are formed in the substrate diffusion region in a respective comer of the substrate region. The four diffusion regions are spaced-apart such that a substrate channel region is defined between each adjacent pair of substrate diffusion regions. A common conductive gate electrode is formed to have four fingers, each one of the fingers extending over a corresponding substrate channel region. The fingers of the common conductive gate electrode are spaced-apart from the underlying substrate channel regions by dielectric material formed therebetween.

Abstract: A short/narrow high performance MOSFET structure in accordance is formed in a semiconductor substrate having a first conductivity type. A first linear sequence of diffusion regions having a second conductivity type is formed in the semiconductor substrate. Each diffuision region in the first sequence is spaced-apart from the prior diffusion region in the first sequence to define a substrate channel region between adjacent diffusion regions. A second linear sequence of diffusion regions having the second conductivity type is also formed in the substrate. As in the case of the first linear sequence, each diffusion region in the second sequence is spaced-apart from the prior diffusion region in the sequence to define s substrate channel region between adjacent diffusion regions in the sequence. Dielectric material is formed in the substrate between the first and second diffusion region sequences to provide electrical isolation between the two sequences.

Abstract: The present invention provides a narrow/short high performance MOS device structure that includes a rectangular-shaped semiconductor substrate region having a first conductivity type. A region of dielectric material is formed at the center of the substrate region. Four substrate diffusion regions, each having a second conductivity type opposite the first conductivity type, are formed in the substrate diffusion region in a respective comer of the substrate region. The four diffusion regions are spaced-apart such that a substrate channel region is defined between each adjacent pair of substrate diffusion regions. A common conductive gate electrode is formed to have four fingers, each one of the fingers extending over a corresponding substrate channel region. The fingers of the common conductive gate electrode are spaced-apart from the underlying substrate channel regions by dielectric material formed therebetween.

Abstract: A silicon-germanium alloy of high crystal quality and containing uniform concentrations of dopant and germanium is formed by applying laser energy to a doped amorphous/polysilicon germanium layer overlying epitaxial silicon. Energy transferred from the laser beam causes melting of the germanium and the underlying silicon, resulting in diffusion of germanium and dopant into the melted silicon. Subsequent cooling and crystallization of the silicon/germanium/dopant melt produces a high quality crystal lattice uniformly incorporating germanium and dopant within its structure. Efficient energy transfer from the laser beam to the underlying germanium and silicon may be promoted by patterning an anti-reflective coating over the amorphous/polysilicon doped germanium prior to exposure to laser radiation. The process is particularly suited for forming the silicon-germanium base of a heterojunction bipolar transistor device.

Abstract: A method of fabricating a bipolar transistor structure is provided in which a blanket silicon-germanium (SiGe) film is used in a self-aligned manner to form the active base region of the bipolar device, thereby eliminating the need for a complicated selective SiGe process.

Abstract: A method of fabricating a bipolar transistor structure is provided in which a blanket silicon-germanium (SiGe) film is used in a self-aligned manner to form the active base region of the bipolar device, thereby eliminating the need for a complicated selective SiGe process.

Abstract: A method is provided for forming a uniformly salicided single crystal silicon emitter structure in a semiconductor integrated circuit bipolar transistor structure. The bipolar transistor structure includes a collector region that has a first conductivity type formed in a semiconductor substrate and a base region having a second conductivity type, opposite the first conductivity type, formed in the collector region. A layer of dielectric material is formed on the surface of the base region. An emitter window is opened in the layer of dielectric material to expose a surface area of the base region. A layer of polysilicon is then formed over the layer of dielectric material and extending into the emitter window such that at least a portion of the layer of polysilicon is in contact with the surface area of the base region. Dopant of the first conductivity type is then introduced into the layer of polysilicon.

Abstract: Method is provided for forming an emitter structure in a semiconductor integrated circuit bipolar transistor structure. The bipolar transistor structure includes a collector region that has a first conductivity type formed in a semiconductor substrate and a base region having a second conductivity type, opposite the first conductivity type, formed in the collector region. A layer of dielectric material is formed on the surface of the base region. An emitter window is opened in the layer of dielectric material to expose a surface area of the base region. A layer of conductive material is then formed over the layer of dielectric material and extending into the emitter window such that at least a portion of the layer of conductive material is in contact with the surface area of the base region. Dopant of the first conductivity type is then introduced into the layer of conductive material.

Abstract: Extremely high dopant concentrations are uniformly introduced into a semiconductor material by laser annealing aided by an anti-reflective coating (ARC). A spin-on-glass (SOG) film containing dopant is formed on top of the semiconductor material. An ARC is then formed over the doped SOG layer. Application of radiation from an excimer laser to the ARC heats and melts the doped SOG film and the underlying semiconductor material. During this melting process, dopant from the SOG film diffuses uniformly within the semiconductor material. Upon removal of the laser radiation, the semiconductor material cools and crystallizes, evenly incorporating the diffused dopant within its lattice structure. The ARC suppresses reflection of the laser by the doped material, promoting efficient transfer of energy from the laser to heat and melt the underlying doped layer and semiconductor material.

Abstract: Stable suicides are formed utilizing excimer laser crystallization in place of a conventional second high temperature rapid thermal processing annealing step. Specifically, thermally unstable silicide having a metal-rich surface layer is conventionally formed utilizing deposition of refractory metal followed by low temperature annealing. After removal of unreacted refractory metal, an amorphous silicon film is deposited on top of the unstable silicide and exposed to radiation from an excimer laser, such that the amorphous silicon melts, reacts with refractory metal from the underlying unstable silicide, and reforms as thermally stable silicide evidencing low electrical resistance.

Abstract: A method is provided involving re-slicing a wafer after dual-side alignment and processing has been performed. This procedure provides twice as many processed electronic devices without increasing the number of loading, processing and unloading procedures performed or the total number of substrates used. Another method is provided for creating two processed chips by attaching two conventional substrates, processing IC's on each of the two exposed, polished sides and then detaching the substrates. This technique reduces the number of loading, processing and unloading procedures required to produce a given number of IC chips by half. An apparatus and further method provides two different subsystems of a single IC processed on opposite sides of the same chip. Such a device saves cost by using fewer substrates to make the same number of chips. Also, the method performs loading, processing and unloading procedures half as much to produce a given number of IC's.

Abstract: A process for forming metal salicide layers on an MOS transistor structure that reduces the risk of forming metal silicide bridges between source/drain regions and a polysilicon gate. The process includes the use of a uni-directional ion metal plasma deposition step to deposit a metal layer on the surface of a MOS transistor structure such that the ratio of the metal layer thickness on the surface of a gate sidewall spacers to the metal layer thickness on the surface of a polysilicon gate is no greater than 0.2. The relatively thin metal layer on the surface of the gate sidewall spacer reduces the possibility of forming metal silicide defects.

Abstract: In a method of introducing phosphorous into an undoped gate polysilicon region formed as part of an integrated circuit structure, an initial MOS structure is developed utilizing conventional techniques through the lightly doped drain (LDD) implant step, with the exception, that, in this case, the gate polysilicon remains undoped. In accordance with the invention, dopant is then implanted into the source/drain regions such that the undoped gate polysilicon is amorphized, thereby eliminating the polysilicon grain boundaries. A CVD oxide layer is then formed and a CMP step is performed to expose the amorphized gate polysilicon region. A phosphorous oxychloride (POCl.sub.3) layer is then formed over the amorphized gate polysilicon and thermally annealed to drive phosphorous from the POCl.sub.3 layer into the polysilicon. The POCl.sub.3 layer is then removed.

Abstract: In a method of introducing phosphorous from phosphorous oxychloride (POCl.sub.3) into an undoped gate polysilicon region formed as part of an integrated circuit structure, an initial MOS structure is developed utilizing conventional techniques through the formation of a layer of undoped polysilicon over thin gate oxide. A POCl.sub.3 layer is then formed over the undoped polysilicon and thermally annealed to drive phosphorous into the gate polysilicon to achieve a desired conductivity level. The phosphorous-rich organic layer is then cleaned from the surface of the POCl.sub.3 using sulfuric peroxide and the POCl.sub.3 layer is removed using a DI:HF solution to expose the surface of the doped polysilicon. After formation of a photoresist gate mask, arsenic, or another heavy ion species, is implanted into the exposed polysilicon to amorphized the exposed poly, thereby eliminating the polysilicon grain boundaries.

Abstract: In a metal oxide semiconductor field effect transistor fabrication process, refractory metal is deposited over designated source and drain areas within a silicon substrate. Refractory metal and silicon at the interface is then mixed by ion implantation of a heavy neutral ion species such as germanium. To minimize source/drain junction depth, the source and drain locations can be subjected to bombardment by a lighter ion such as silicon which amorphizes silicon to a predetermined depth under the designated source and drain regions and so substantially confines dopant diffusion to the silicon amorphized region. To render the source and drain of desired conductivity type, an ion implantation of a non-neutral ion is then performed.

Abstract: A vertically integrated CMOS logic gate has spaced semiconductor layers with control gates located between the layers and insulated from them by gate oxide. Transistors formed in one semiconductor layer are vertically aligned with transistors formed in the other semiconductor layer. Pairs of vertically coincident transistors have common control gates and certain of the pairs have integral drain regions. Transistors in one layer are series connected in an open loop configuration and transistors in the other layer are parallel connected in a closed loop configuration. The logic gate function depends on voltages applied to the common control gates and to the open and closed loops. By the vertical integration, a two-input NAND or NOR gate can be made using less area than that required for two simple MOS transistors.

Abstract: In a stacked metal-oxide-semiconductor (SMOS) transistor, the transistor source, drain and channel each have a lower part formed in a silicon substrate and an upper part composed of recrystallized polysilicon. The device gate is located between the upper and lower channel parts. By vertically integrating a MOS transistor, performance limitations imposed by the direct scaling approach to device miniaturization are avoided.