Abstract: A method of forming a contact hole in an interlevel dielectric layer using dual etch stops includes the steps of providing a semiconductor substrate, forming a gate over the substrate, forming a source/drain region in the substrate, providing a source/drain contact electrically coupled to the source/drain region, forming an interlevel dielectric layer that includes first, second and third dielectric layers over the source/drain contact, forming an etch mask over the interlevel dielectric layer, applying a first etch which is highly selective of the first dielectric layer with respect to the second dielectric layer through an opening in the etch mask using the second dielectric layer as an etch stop, thereby forming a first hole in the first dielectric layer that extends to the second dielectric layer without extending to the third dielectric layer, applying a second etch which is highly selective of the second dielectric layer with respect to the third dielectric layer through the opening in the etch mask usi

Abstract: Various processes are provided for producing a p-channel and/or n-channel transistor. The present processes are thereby applicable to NMOS, PMOS or CMOS integrated circuits, any of which derive a benefit from having an asymmetrical LDD structure. The asymmetrical structure can be produced on a p-channel or n-channel transistor in various ways. According, the present process employs various techniques to form an asymmetrical transistor. The various techniques employ processing steps which vary depending upon the LDD result desired. First, the LDD implant can be performed only in the drain-side of the channel, or in the drain-side as well as the source-side. Second, the gate conductor sidewall surface adjacent the drain can be made thicker than the sidewall surface adjacent the source.

Abstract: A method of making an asymmetrical IGFET and isolating active regions is disclosed.

Abstract: A multi-dimensional transistor structure is fabricated which includes a base transistor substrate upon which transistors are formed. An elevated substrate is formed overlying the base transistor and having an oxide isolation formed in localized regions beneath the elevated substrate but overlying the base transistor substrate. A plurality of transistors are formed on a substrate wafer to form a base-level transistor formation. An intralevel dielectric (ILD) layer is deposited overlying the base-level transistor formation. Overlying the ILD layer, a "sandwich" structure is formed with the deposition of a first polysilicon layer, deposition of an oxide isolation layer, and deposition of a second polysilicon layer.

Abstract: Various processes are provided for producing a p-channel and/or n-channel transistor. The present processes are thereby applicable to NMOS, PMOS or CMOS integrated circuits, any of which derive a benefit from having an asymmetrical LDD structure. The asymmetrical structure can be produced on a p-channel or n-channel transistor in various ways. According, the present process employs various techniques to form an asymmetrical transistor. The various techniques employ processing steps which vary depending upon the LDD result desired. First, the LDD implant can be performed only in the drain-side of the channel, or in the drain-side as well as the source-side. Second, the gate conductor sidewall surface adjacent the drain can be made thicker than the sidewall surface adjacent the source.

Abstract: An integrated circuit fabrication process is provided in which an elevated doped polysilicon structure may be formed and isolated from another polysilicon structure lying in the same elevated plane. The elevated structure may serve as a junction area of a transistor formed entirely within and upon the elevated polysilicon. The elevated structure frees up space within the lower level substrate for additional transistors and/or lateral interconnect, a benefit of which is to promote higher packing density within the integrated circuit. A first transistor is provided which is disposed upon and within a silicon-based substrate. A primary interlevel dielectric is deposited across the transistor and the substrate. Polysilicon may then be deposited across the primary interlevel dielectric and doped using ion implantation. A second transistor may be formed upon and within a portion of the polysilicon layer.

Abstract: An elevated transistor formation includes a plurality of planes upon which transistors are formed. The plurality of transistor planes are formed at multiple relative elevations overlying a substrate wafer using deposited polysilicon to form a substrate between the layers. The polysilicon is deposited in a multiple-grain form to achieve an advantageous balance between deposition rate and substrate quality. In particular, columnar polysilicon is deposited at a temperature of approximately 620.degree. C. and above to achieve a high deposition rate directly overlying a lower-elevation transistor plane. High quality polysilicon is then deposited overlying the columnar polysilicon layer at a temperature of approximately 580.degree. C. or below. The deposition rate for high quality polysilicon is substantially lower than the deposition rate for columnar polysilicon. The highest quality substrate, upon which transistors in an elevated transistor plane are formed, is amorphous polysilicon.

Abstract: A composite gate electrode layer incorporates a diffusion-retarding barrier layer disposed at the bottom of the gate electrode layer to reduce the amount of dopant which diffuses into the gate dielectric layer from the gate electrode layer. A lower nitrogen-containing gate electrode layer provides a diffusion-retarding barrier layer against dopant diffusion into the gate dielectric layer disposed therebelow, and an upper gate electrode layer is formed upon the lower layer and is doped to form a highly conductive layer. Together the first and second gate electrode layers form a composite gate electrode layer which incorporates a diffusion-retarding barrier layer adjacent to the underlying gate dielectric layer. The barrier layer may be formed by annealing a first polysilicon layer in a nitrogen-containing ambient, such as N.sub.2, NO, N.sub.2 O, and NH.sub.

Abstract: A semiconductor device and process for manufacture thereof is disclosed in which an elevated, active polysilicon region is formed by forming a gate electrode/nitride layer structure on a surface of a semiconductor substrate with spacers formed on adjacent walls to define an active region of the substrate. A thick polysilicon layer is formed over the resultant structure and then planarized leaving a portion of the polysilicon layer above the active region of the substrate. The remaining portion is doped to form an elevated active region.

Abstract: A process is provided for producing active and passive devices on various levels of a semiconductor topography. As such, the present process can achieve device formation in three dimensions to enhance the overall density at which an integrated circuit is formed. The multi-level fabrication process not only adds to the overall circuit density but does so with emphasis placed on interconnection between devices on separate levels. Thus, high performance interconnect is introduced whereby the interconnect is made as short as possible between features within one transistor level to features within another transistor level. The interconnect achieves lower resistivity and capacitance by forming a single gate conductor which is shared by an upper level transistor and a lower level transistor. The shared gate conductor is interposed between a pair of gate dielectrics and each gate dielectric is configured between the single gate conductor and a respective substrate.

Abstract: An IGFET with a gate electrode and a source contact in a trench is disclosed. The IGFET includes a trench with opposing sidewalls and a bottom surface in a semiconductor substrate, a gate insulator on the bottom surface, a gate electrode on the gate insulator, a source contact on the bottom surface, insulative spacers between the gate electrode, the source contact and the sidewalls, and a source and drain adjacent to the bottom surface.

Abstract: A process for forming a semiconductor device having an elevated active region is disclosed. The process includes forming a plurality of gate electrodes on the semiconductor substrate and disposing a thick oxide layer over the gate electrodes. A trench is formed in a thick oxide layer and is filled with a polysilicon material. The polysilicon material is subsequently doped in order to form an elevated active region above an active region of the substrate.

Abstract: A process is provided for producing active and passive devices on various levels of a semiconductor topography. As such, the present process can achieve device formation in three dimensions to enhance the overall density at which an integrated circuit is formed. The multi-level fabrication process not only adds to the overall circuit density, but does so with emphasis placed on high performance interconnection between devices on separate levels. The interconnect configuration is made as short as possible between features within one transistor level to features within another transistor level. This interconnect scheme lowers resistivity by forming a gate conductor of an upper level transistor upon a gate conductor of lower level transistor. Alternatively, the gate conductors can be a single conductive entity. In order to abut the gate conductors together, or form a single gate conductor, the upper level transistor is inverted relative to the lower level transistor.

Abstract: A method is provided for forming a transistor in which capacitive coupling between the gate conductors and adjacent structures employed by the integrated circuit is reduced. According to an embodiment, a gate conductor is dielectrically spaced above a semiconductor substrate, and a masking structure is arranged upon an upper surface of the gate conductor. A source/drain implant self-aligned to opposed lateral sidewalls of the masking structure is performed to form source/drain implant areas within the substrate. Select portions of the gate conductor are removed such that opposed ends of the masking structure extend beyond opposed sidewall surfaces of the gate conductor. A lightly doped drain implant self-aligned to the opposed sidewall surfaces of the narrowed gate conductor is performed to form lightly doped drain implant areas within the substrate.

Abstract: An improved series and/or parallel connection of transistors within a logic gate is presented. The improved connection is brought about by a sacrificial structure on which gate conductors are formed adjacent sidewall surfaces of the sacrificial structure. The sacrificial structure thereby provides spacing between the series-connected or parallel-connected transistors. Upon removal of each sacrificial structure, a pair of transistors can be formed by implanting dopant species into the substrate on opposite sides of the spaced conductors. Beneath what was once a sacrificial structure is a shared implant area to which two transistors are coupled either in series or in parallel. By depositing the gate conductor material and then anisotropically removing the material except adjacent the vertical sidewall surfaces, an ultra short gate conductor can be formed concurrent with other gate conductors within a logic gate.

Abstract: A process is provided for producing active and passive devices on various levels of a semiconductor topography. As such, the present process can achieve device formation in three dimensions to enhance the overall density at which an integrated circuit is formed. The multi-level fabrication process not only adds to the overall circuit density but does so with emphasis placed on interconnection between devices on separate levels. Thus, high performance interconnect is introduced whereby the interconnect is made as short as possible between features within one transistor level to features within another transistor level. The interconnect achieves lower resistivity by forming a gate conductor of an upper level transistor upon a gate conductor of a lower level transistor. In order to abut the gate conductors together, the upper level transistor is inverted relative to the lower level transistor.

Abstract: A process is provided for forming a transistor gate conductor having an etch stop arranged at a depth below its upper surface such that the lateral width of the gate conductor above the etch stop may be exclusively narrowed to provide for reduction of transistor channel length. A masking layer, i.e., photoresist, patterned above the gate conductor is isotropically etched so as to minimize its lateral width prior to etching the gate conductor. Portions of the gate conductor not protected by the photoresist may be etched from above the etch stop to define a new pair of opposed sidewall surfaces for the upper portion of the gate conductor. The lateral width of the upper portion of the gate conductor thus may be reduced to a smaller dimension than that of conventional gate conductors. The gate conductor is subjected to an anisotropic etch in which portions of the gate conductor not protected by the narrowed photoresist are etched down to the etch stop.

Abstract: A semiconductor process in which a dielectric layer is formed on an upper surface of a semiconductor substrate which includes a silicon base layer. Thereafter, an upper silicon layer is formed on an upper surface of the dielectric layer. The dielectric layer and the upper silicon layer are then patterned to form first and second silicon-dielectric stacks on the upper surface of the base silicon layer. The first and second silicon-dielectric stacks are laterally displaced on either side of a channel region of the silicon substrate and each include a proximal sidewall and a distal sidewall. The proximal sidewalls are approximately coincident with respective boundaries of the channel region. Thereafter, proximal and distal spacer structures are formed on the proximal and distal sidewalls respectively of the first and second silicon-dielectric stacks. A gate dielectric layer is then formed on exposed portions of the silicon base layer over a channel region of the base silicon layer.

Abstract: A process is provided for producing active and passive devices on various levels of a semiconductor topography. As such, the present process can achieve device formation in three dimensions to enhance the overall density at which an integrated circuit is formed. The multi-level fabrication process not only adds to the overall circuit density but does so with emphasis placed on interconnection between devices on separate levels. Thus, high performance interconnect is introduced whereby the interconnect is made as short as possible between features within one transistor level to features within another transistor level. The interconnect employs a via routed directly between a well of an upper level transistor to a well of a lower transistor so as to effect direct coupling between the wells of the respective transistors. Direct coupling in this fashion affords consistent operation of transistors arranged on separate elevation levels.

Abstract: A method of growing an oxide film in which the upper surface of a semiconductor substrate is cleaned and the semiconductor substrate is dipped into an acidic solution to remove any native oxide from the upper surface. The substrate is then directly transferred from the acidic solution to an oxidation chamber. The oxidation chamber initially contains an inert ambient maintained at a temperature of less than approximately 500.degree. C. The transfer is accomplished without substantially exposing the substrate to oxygen thereby preventing the formation of a native oxide film on the upper surface of the substrate. Thereafter, a fluorine terminated upper surface is formed on the semiconductor substrate. The temperature within the chamber is then ramped from the first temperature to a second or oxidizing temperature if approximately 700.degree. C. to 850.degree. C. The presence of the fluorine terminated upper surface substantially prevents oxidation of the semiconductor substrate during the temperature ramp.