Abstract: A method of fabricating self aligned static induction transistors. The method comprises fabricating an N silicon on N.sup.- silicon substrate having an active area. A guard ring is formed around the active area. An N.sup.+ polysilicon layer is formed that comprises source and gate regions. An oxide layer is formed on the N.sup.+ polysilicon layer. A second polysilicon layer is formed on the oxide layer. A second oxide layer is formed on the second polysilicon layer which is then masked by a self aligning mask. Trenches are etched into the substrate using the self aligning mask and gate regions are formed at the bottom of the trenches. A first layer of metal (gate metal) is deposited to make contact with the gate regions. A layer of photoresist is deposited and planarized, and the first layer of metal is overetched below the top surface of the trench. Plasma nitride is deposited and planarized, and a polysilicon mask is deposited over the planarized layer of plasma nitride.

Abstract: Methods of fabricating heavily doped edges of mesa structures in silicon-on-sapphire and silicon-on-insulator semiconductor devices. The methods are self-aligning and require a minimum of masking steps to achieve. The disclosed methods reduce edge leakage and resolve N-channel threshold voltage instability problems. Mesa structures are formed that comprise N-channel and P-channel regions having a thermal oxide layer deposited thereover. A doping layer of borosilicate glass, or alternatively, an undoped oxide layer that is subsequently implanted, is deposited over the mesa structures. In the first method, the doping layer is etched by means of an anisotropic plasma etching procedure to form oxide spacers at the edges of the mesa structures. The doping layer is removed from the N-mesa structures using an N-channel mask and wet oxide etching procedure. The structure is then heated to a relatively high temperature to drive the dopant into the edges of the N-channel mesa structures.

Abstract: A method of fabricating higher-order metal interconnection layers in a multi-level metal semiconductor device. The semiconductor device has at least one metal layer, an oxide layer disposed on the metal layer, and a metal plug disposed in the oxide layer connected to the metal layer. A reverse photoresist mask is formed on the oxide layer that is etched to form trenches therein that define the higher-order metal layer. An adhesion layer that comprises titanium tungsten or aluminum is deposited on top of the photoresist mask that contacts the metal plug. A low viscosity photoresist layer is then deposited on top of the adhesion layer. The adhesion layer and low viscosity photoresist layer are then anisotropically etched, and the low viscosity photoresist layer is then removed to expose the adhesion layer. Finally, selective metal, such as tungsten or molybdenum, for example, is deposited on top of the adhesion layer in the trench to form the higher-order metal interconnection layer.

Abstract: Methods of fabricating metal interconnection lines in an integrated circuit. In general, one method comprises the steps of depositing a layer of metal on an inter-dielectric oxide layer. The layer of metal is patterned and etched to form metal interconnection lines over the oxide layer. Tungsten is selectively deposited onto the etched layer to completely form the metal interconnection lines. Additionally, in a second method, a layer of tungsten may be deposited prior to the layer of metal. This forms a metal line that is completely encapsulated in tungsten. In addition, selective tungsten employed to repair broken metal lines in a fabricated integrated circuit. The selective tungsten is deposited using a chemical vapor deposition process and is deposited onto masked and etched second level (or higher) metal lines formed in the integrated circuit. The method of selectively depositing tungsten comprises the steps of exposing the metal interconnection lines to a mixture of SiH.sub.

Abstract: A technique is disclosed for obtaining a self-aligned twin-well structure in a CMOS process. A double layer of two different photoresist materials is employed to obtain an overhang photoresist structure used for the p-well masking and ion implantation process. After the p-well implantation, pure aluminum is deposited over the wafer, forming a first layer over the p-well region and a second layer over the photoresist layers. A metal lift-off procedure is performed to dissolve the photoresist layers and thereby remove the second layer of metal. The first layer of aluminum remaining on the wafer forms a conjugate of the p-well pattern and serves as the n-well mask for ion implantation. The invention provides a straightforward method for achieving the self-aligned twin-well structure in CMOS processes, and is adapted to high energy ion implantation for achieving retrograde impurity profiles.

Abstract: A photolithographic process useful for VLSI fabrication is disclosed for achieving side-wall profile control of poly lines, metal lines, contact and via openings. Layers of a first and second photoresist materials are formed on the poly, metal or oxide-covered substrate. The top layer is patterned by conventional processes to define the final device geometry. The bottom layer is exposed and over-developed to form an overhang structure about the line pattern or the contact/via opening. During the subsequent anisotropic plasma-assisted etching step, some ions or particles are passed obliquely over the overhang and bombard the opening corner, the side-wall and the under-cut area. The plasma-assisted etching step not only forms the poly or metal lines, or the contact or via opening, but also results in an opening with rounded corners and a smoothly tapered side-wall profile. The subsequent metal film deposition step results in a uniform film thickness around the edges of the opening.