Abstract: A low dielectric constant multiple carbon-containing silicon oxide dielectric material for an integrated circuit structure is described which comprises a silicon oxide material including silicon atoms which are each bonded to a multiple carbon-containing group consisting of carbon atoms and primary hydrogens. Preferably such multiple carbon-containing groups have the general formula —(C)y(CH3)z, where y is an integer from 1 to 4 for a branched alkyl group and from 3 to 5 for a cyclic alkyl group, and z is 2y+1 for a branched alkyl group and 2y−1 for a cyclic alkyl group.

Abstract: A MOSFET having a buried channel structure and an adjacent surface channel structure between a source region and a drain region. The surface channel structure is preferably formed adjacent the source region via angular implantation techniques. By combining the advantages of the surface channel device with the buried channel device, the resulting hybrid MOSFET structure has improved drive current and switching characteristics.

Abstract: Lifetime of a short-channel NMOS device is increased by modifying distributions of electrically active LDD dopant at boundaries of the device's LDD regions. The LDD dopant distributions are modified by implanting counter-dopants at the boundaries of the LDD regions. Group III counter-dopants such as boron and group IV elements such as silicon alter activation properties of the LDD dopant. The dopant distributions are modified at the device's n-junctions to reduce the maximum electric field displacement at an interface defined by the device's gate and substrate. The dopant distributions can be further modified to shape the n-junctions such that hot carriers are injected away from the gate.

Abstract: An isolation trench in a silicon semiconductor substrate is provided with a barrier region containing nitrogen atoms formed in the trench, contiguous with the silicon semiconductor substrate surfaces of the trench. The novel isolation trench structure of the invention is formed by forming an isolation trench in a silicon semiconductor substrate; forming in the isolation trench a barrier region by treating the trench structure with nitrogen atoms from a nitrogen plasma; and then forming a silicon oxide layer over the barrier region in the trench to confine the nitrogen atoms in the barrier region. In a preferred embodiment, a silicon oxide liner is first formed over the silicon semiconductor substrate surfaces of the trench, and then the trench structure is treated with nitrogen atoms from a nitrogen plasma to form, on the silicon semiconductor substrate surfaces of the trench, a barrier layer which contains silicon atoms, oxygen atoms, and nitrogen atoms.

Abstract: Reduction in the net charge at the interface of a dielectric and a semiconductor material is achieved by placing atomic species in the dielectric near the interface. Preferably, these species are selected from the group of alkaline earth metals. The presence of these atoms results in a redistribution of the electronic density near the interface. The placement of the atoms is effected by ion implantation followed by multiple annealing steps at alternating low and high temperatures.

Abstract: A silicon semiconductor integrated circuit includes an insulative field oxidation layer which substantially does not encroach under active circuit elements of the integrated circuit. The field oxidation layer is formed of oxidized amorphous silicon created by bombardment of a silicon substrate with noble gas ions. The amorphous silicon oxidizes at a rate much faster than crystalline silicon so that when the field oxidation layer is formed crystalline silicon foundations for the active circuit elements are left substantially intact. The crystalline silicon foundations are formed by using appropriate shield elements during the noble gas ion bombardment. This noble gas ion bombardment also has the advantage of eliminating dislocation defects which may be present in the field oxidation area so that these defects do not propagate into the crystal lattice of the silicon during subsequent heating and cooling cycles.

Abstract: A method of forming a supersaturated layer on a semiconductor device, where an initial phase layer is deposited on the semiconductor device. The initial phase layer has a solid phase dopant saturation level and a liquid phase dopant saturation level, where the liquid phase dopant saturation level is greater than the solid phase dopant saturation level. A concentration of a dopant is impregnated within the initial phase layers, where the concentration of the dopant is greater than the solid phase dopant saturation level and no more than about the liquid phase dopant saturation level. The initial phase layer is annealed, without appreciably heating the semiconductor device, using an amount of energy that is high enough to liquefy the initial phase layer over a melt duration. This dissolves the dopant in the liquefied initial phase layer. The amount of energy is low enough to not appreciably gasify or ablate the initial phase layer.

Abstract: Provided are methods for fabricating hardened composite thin layer gate dielectrics. According to preferred embodiments of the present invention, composite gate dielectrics may be produced as bilayers having oyxnitride portions with nitrogen contents above 10 atomic percent, while avoiding the drawbacks of prior art nitridization methods. In one aspect of the present invention, a hardened composite thin layer gate dielectric may be formed by deposition of a very thin silicon layer on a very thin oxide layer on a silicon substrate, followed by low energy plasma nitridization and subsequent oxidation of the thin silicon layer. In another aspect of the invention, low energy plasma nitridization of a thin oxide layer formed on a silicon substrate may be followed by deposition of a very thin silicon layer and subsequent oxidation, or additional low energy plasma nitridization and then oxidation, of the thin silicon layer.

Abstract: A crystalline semiconductor gate electrode having a re-entrant geometry and a process for making same are disclosed. The novel gate electrode may be formed from a polysilicon layer on a substrate by first implanting a masked polysilicon layer with a neutral species, i.e., a species which will not introduce a dopant into the polysilicon, such as a Group IV element, e.g., silicon, or a Group VIII element, e.g., argon. The neutral species is implanted into the masked polysilicon layer at an angle to provide a tapered implanted region which undercuts one side of the length (long dimension) of the mask. The substrate may then be rotated 180.degree. and then again implanted to provide a tapered implanted region which undercuts the opposite side of the length of the mask. When gate electrodes with such re-entrant geometry are to be formed on a substrate with their long axes at right angles to one another, i.e.

Abstract: Provided is a method of fabricating gate dielectric layers having variable thicknesses and compositions over different regions of a semiconductor wafer. In a preferred embodiment of the present invention, a gate oxide layer is first grown over the various regions. Regions that are to have a relatively thicker, unhardened gate dielectric are masked and the wafer is exposed to a remote low energy nitrogen plasma. After the nitridization process is completed, the mask is removed and the wafer is exposed to further oxidation. The regions where oxynitrides have been formed act as a barrier to the oxidation process. Consequently, different oxide thicknesses can be grown on the same wafer, thinner and hardened where nitridization has been performed, and thicker and not hardened in those regions that were masked during the nitridization.

Abstract: A retrograde well in a CMOS device is formed by using a low energy ion implanter. Dopant atoms are implanted into a bare surface of the device's substrate, in a direction that is orthogonal to the surface of the substrate (for a substrate having a <100> orientation). The well implant can be performed at an energy below 220 keV. Chained implants for a punch-through barrier in the retrograde well can be performed after the well implant. When the substrate is annealed, the punch-through barrier is activated at the same time as the retrograde well.

Abstract: A transistor gate array includes an active transistor region (50a-50n) of transistor gates all oriented in a single direction. Surrounding the active transistor region on all four sides are input/output regions (52a-52d) each containing a row of input/output transistors. All of the I/O devices on all sides of the array are oriented in the same common direction, which is the same direction as the orientation of the active transistor in the active region. This arrangement allows the use of the benefits of high angle ion implantation with fewer ion implant steps. Where some of the transistors are oriented at right angles to others, as in the prior art, four separate directions of high angle ion implantation are required to avoid degradation of electrical properties. With all transistors, including those of the gate array and those of the input/output devices, all oriented in the same direction, only two directions high angle ion implantation are required.

Abstract: A process is disclosed for forming one or more doped regions beneath the surface of a single crystal semiconductor substrate, such as retrograde wells or deeper source/drain regions, by implantation at low energy which comprises orienting the crystal lattice of the semiconductor substrate, with respect to the axis of the implantation beam, i.e., the path of the energized atoms in the implantation beam, to maximize the number of implanted atoms which pass between the atoms in the crystal lattice. This results in the peak concentration of implanted atoms in the crystal lattice of the single crystal semiconductor substrate being deeper than the peak concentration of implanted atoms in the substrate would be if the axis of the implantation beam were not so oriented with respect to the crystal lattice of the semiconductor substrate during implantation.

Abstract: Rapid Thermal Processing of a semiconductor wafer is performed by scanning a laser beam across a silicon dioxide film in contact with a surface of the wafer. The silicon dioxide film absorbs the energy from the laser beam and converts the energy to heat. The heat, in turn, is transferred to the wafer. Temperature feedback can be obtained to increase control and uniformity of temperatures across the wafer.

Abstract: Rapid Thermal Processing of a semiconductor wafer is performed by scanning a laser beam across a silicon dioxide film in contact with a surface of the wafer. The silicon dioxide film absorbs the energy from the laser beam and converts the energy to heat. The heat, in turn, is transferred to the wafer. Temperature feedback can be obtained to increase control and uniformity of temperatures across the wafer.

Abstract: A novel integrated circuit structure, and process for making same, is disclosed wherein a tapered or gradient doped profile region is provided in a semiconductor substrate between the heavily doped drain region and the channel region in the substrate comprising an MOS device. In the process of the invention, a re-entrant or tapered gate electrode, resembling an inverted trapezoid, is used as a mask during a first doping step at a dosage level higher than normally used to form a conventional LDD region. This doping step forms a doped region having a dopant gradient which gradually increases in dosage level with distance from the channel region. Conventional oxide spacers may then be formed on the sidewalls of the gate electrode followed by conventional high level doping to form the heavily doped source and drain region in the unmasked portions of the substrate between the oxide spacers and the field oxide isolation.

Abstract: Formation of a barrier region in a single crystal group IV semiconductor substrate at a predetermined spacing from a doped region in the substrate is described to prevent or inhibit migration of dopant materials from an adjacent doped region through the barrier region. By implantation of group IV materials into a semiconductor substrate to a predetermined depth in excess of the depth of a doped region, a barrier region can be created in the semiconductor to prevent migration of the dopants from the doped region through the barrier region. The treatment of the single crystal substrate with the group IV material is carried out at a dosage and energy level sufficient to provide such a barrier region in the semiconductor substrate, but insufficient to result in amorphization (destruction) of the single crystal lattice of the semiconductor substrate.

Abstract: A uniformly doped polysilicon gate electrode of an MOS device forming a part of an integrated circuit structure on a semiconductor substrate is formed by first depositing a very thin layer of amorphous or polycrystalline silicon, e.g., from about 2 nm to about 10 nm, over a gate oxide layer. The thin layer of silicon layer is then exposed to a nitrogen plasma formed from N.sub.2 at a power level sufficient to break the silicon--silicon bonds in the thin layer of silicon, but insufficient to cause sputtering of the silicon to cause a barrier layer of silicon and nitrogen to form at the surface of the thin silicon layer. Further silicon, e.g., polysilicon, is then deposited over the barrier layer to the desired thickness of the polysilicon gate electrode. The gate electrode is then conventionally doped, i.e.

Abstract: Rapid Thermal Processing of a semiconductor wafer is performed by scanning a laser beam across a silicon dioxide film in contact with a surface of the wafer. The silicon dioxide film absorbs the energy from the laser beam and converts the energy to heat. The heat, in turn, is transferred to the wafer. Temperature feedback can be obtained to increase control and uniformity of temperatures across the wafer.

Abstract: A process and resulting product is described for forming an oxide in a semiconductor substrate which comprises initially implanting the substrate with atoms of a noble gas, then oxidizing the implanted substrate at a reduced temperature, e.g., less than 900.degree. C., to form oxide in the implanted region of the substrate, and then etching the oxidized substrate to remove a portion of the oxide. The resulting oxidation produces a dual layer of oxide in the substrate. The upper layer is an extremely porous and frothy layer of oxide, while the lower layer is a more dense oxide. The upper porous layer of oxide can be selectively removed from the substrate by a mild etch, leaving the more dense oxide layer in the substrate. Further oxide can then be formed adjacent the dense layer of oxide in the substrate, either by oxide deposition over the dense oxide or by growing further oxide beneath the dense oxide layer.