Abstract: A capacitor structure characterized by improved capacitance as a result of increasing the capacitance associated with charge spreading that occurs within the electrodes of the capacitor. The electrodes are formed of superconducting or high-dielectric constant conductor materials, and are preferably used in combination with high-dielectric constant insulator materials. The capacitor structures are particularly suited as thin-film capacitors of the type used for high-density applications such as DRAM.

Abstract: A semiconductor device (and method for forming the device) includes a silicon-on-insulator (SOI) wafer formed on a substrate surface. An isolation trench in the wafer surface surrounds alternating p-type trenches and n-type trenches and electrically isolates the device from the substrate, thereby allowing the device to be effectively utilized as a differential detector in an optoelectronic circuit.

Abstract: A densely packed array of vertical semiconductor devices having pillars and methods of making thereof are disclosed. The array has rows of wordlines and columns of bitlines. The array has vertical pillars, each having two wordlines, one active and the other passing for each, cell. Two wordlines are formed per pillar on opposite pillar sidewalls which are along the row direction. The threshold voltage of the pillar device is raised on the side of the pillar touching the passing wordline, thereby permanently shutting off the pillar device during the cell operation and isolating the pillar from the voltage variations on the passing wordline. The isolated wordlines allow individual cells to be addressed and written via direct tunneling, in both volatile and non-volatile memory cell configurations. For Gbit DRAM application, stack or trench capacitors may be formed on the pillars, or in trenches surrounding the pillars, respectively.

Abstract: A dynamic random access memory device formed in a substrate having a trench. The trench has a side wall, a top, a lower portion, and a circumference. The device includes a signal storage node including a storage node conductor formed in the lower portion of the trench and isolated from the side wall by a node dielectric and a collar oxide above the node dielectric. A buried strap is coupled to the storage node conductor and contacts a portion of the side wall of the trench above the collar oxide. A trench-top dielectric which is formed upon the buried strap has a trench-top dielectric thickness.

Abstract: A dynamic random access memory device formed in a substrate having a trench. The trench has a side wall, a top, a lower portion, and a circumference. The device includes a signal storage node including a storage node conductor formed in the lower portion of the trench and isolated from the side wall by a node dielectric and a collar oxide above the node dielectric. A buried strap is coupled to the storage node conductor and contacts a portion of the side wall of the trench above the collar oxide. A trench-top dielectric which is formed upon the buried strap has a trench-top dielectric thickness.

Abstract: A method includes forming a trench capacitor in a semiconductor body. A recess is formed in the upper portion of the capacitor with such recess having sidewalls in the semiconductor body. A first material is deposited over the sidewalls and over a bottom of the recess. A second material is deposited over the first material. A mask is provided over the second material. The mask has: a masking region to cover one portion of said recess bottom; and a window over a portion of said recess sidewall and another portion of said recess bottom to expose underlying portions of the second material. Portions of the exposed underlying portions of the second material are selectively removing while leaving substantially un-etched exposed underlying portions of the first material. The exposed portions of the first material and underlying portions of the semiconductor body are selectively removed. An isolation region is formed in the removed portions of the semiconductor body.

Abstract: A densely packed array of vertical semiconductor devices having pillars and methods of making thereof are disclosed. The array has rows of wordlines and columns of bitlines. The array has vertical pillars, each having two wordlines, one active and the other passing for each cell. Two wordlines are formed per pillar on opposite pillar sidewalls which are along the row direction. The threshold voltage of the pillar device is raised on the side of the pillar touching the passing wordline, thereby permanently shutting off the pillar device during the cell operation and isolating the pillar from the voltage variations on the passing wordline. The isolated wordlines allow individual cells to be addressed and written via direct tunneling, in both volatile and non-volatile memory cell configurations. For Gbit DRAM application, stack or trench capacitors may be formed on the pillars, or in trenches surrounding the pillars, respectively.

Abstract: A densely packed array of vertical semiconductor devices, having pillars with stack capacitors thereon, and methods of making thereof are disclosed. The pillars act as transistor channels, and are formed between upper and lower doped regions. The lower doped regions are self-aligned and are located below the pillars. The array has columns of bitlines and rows of wordlines. The lower doped regions of adjacent bitlines may be isolated from each other without increasing the cell size and allowing a minimum area of approximately 4 F.sup.2 to be maintained. The array is suitable for Gbit DRAM applications because the stack capacitors do not increase array area. The array may have an open bitline, a folded, or an open/folded architecture with dual wordlines, where two transistors are formed on top of each other in each trench. The lower regions may be initially implanted. Alternatively, the lower regions may be diffused below the pillars after forming thereof.

Abstract: A densely packed array of vertical semiconductor devices, having pillars and deep trench capacitors, and methods of making thereof are disclosed. The pillars act as transistor channels, and are formed between upper and lower doped regions. The lower doped regions are self-aligned and are located below the pillars. The array has columns of bitlines and rows of wordlines. The lower doped regions of all the cells are isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained. The array is suitable for Gbit DRAM applications because the deep trench capacitors do not increase array area. The array may have an open bitline, a folded, or an open/folded architecture with dual wordlines, where two transistors are formed on top of each other in each trench. The lower regions may be initially implanted. Alternatively, the lower regions may be diffused below the pillars after forming thereof.

Abstract: A densely packed array of vertical semiconductor devices and methods of making thereof are disclosed. The array has columns of bitlines and rows of wordlines. The gates of the transistors act as the wordlines, while the source or drain regions acts as the bitlines. The array also has vertical pillars, acting as a channel, formed between source and drain regions. The source regions are self-aligned and located below the pillars. The source regions of adjacent bitlines are isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained. The isolated sources allow individual cells to be addressed and written via direct tunneling, in both volatile and non-volatile memory cell configurations. The source may be initially implanted. Alternatively, the source may be diffused below the pillars after forming thereof.

Abstract: A densely packed array of vertical semiconductor devices, having pillars and deep trench capacitors, and methods of making thereof are disclosed. The pillars act as transistor channels, and are formed between upper and lower doped regions. The lower doped regions are self-aligned and are located below the pillars. The array has columns of bitlines and rows of wordlines. The lower doped regions of all the cells are isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained The array is suitable for Gbit DRAM applications because the deep trench capacitors do not increase array area. The array may have an open bitline, a folded, or an open/folded architecture with dual wordlines, where two transistors are formed on top of each other in each trench. The lower regions may be initially implanted. Alternatively, the lower regions may be diffused below the pillars after forming thereof.

Abstract: A densely packed array of vertical semiconductor devices having pillars and methods of making thereof are disclosed. The array has columns of bitlines and rows of wordlines. The gates of the transistors act as the wordlines, while the source or drain regions acts as the bitlines. The array also has vertical pillars, each having a channel formed between source and drain regions. Two transistors are formed per pillar. This is achieved by forming two gates per pillar formed on opposite pillar sidewalls which are along the bitline direction. This forms two wordlines or gates per pillar arranged in the wordline direction. The source regions are self-aligned and located below the pillars. The source regions of adjacent bit lines are isolated from each other without increasing the cell size. Two floating gates per pillar may be used for EEPROM or flash memory application.

Abstract: A densely packed array of vertical semiconductor devices, having pillars with stack capacitors thereon, and methods of making thereof are disclosed. The pillars act as transistor channels, and are formed between upper and lower doped regions. The lower doped regions are self-aligned and are located below the pillars. The array has columns of bitlines and rows of wordlines. The lower doped regions of adjacent bitlines may be isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained. The array is suitable for Gbit DRAM applications because the stack capacitors do not increase array area. The array may have an open bitline, a folded, or an open/folded architecture with dual wordlines, where two transistors are formed on top of each other in each trench. The lower regions may be initially implanted. Alternatively, the lower regions may be diffused below the pillars after forming thereof.

Abstract: Decoupled plasma etching process used to make a protruding structure having vertical or near vertical sidewalls. The decoupled plasma etching process comprises the following steps:forming a mask on top of a semiconductor substrate defining the lateral size of the protruding structures to be formed in said substrate,feeding HCl, Cl.sub.2 and N.sub.2 into a plasma chamber to provide an ion plasma when applying source power,causing said ions to diffuse towards the substrate by applying a bias power such that the portions of said substrate not being covered by said mask are etched away, wherein the dosage of HCl, Cl.sub.2 and N.sub.2 is chosen such that newly formed portions of the sidewall surfaces are passivated by by-product of Si, Cl, and N.sub.2 and thus become protected from further being etched. The bias power is less than 70 Watts to ensure that the etching process is predominantly chemical.

Abstract: A densely packed array of vertical semiconductor devices and methods of making thereof are disclosed. The array has columns of bitlines and rows of wordlines. The gates of the transistors act as the wordlines, while the source or drain regions acts as the bitlines. The array also has vertical pillars, acting as a channel, formed between source and drain regions. The source regions are self-aligned and located below the pillars. The source regions of adjacent bitlines are isolated from each other without increasing the cell size and allowing a minimum area of approximately 4F.sup.2 to be maintained. The isolated sources allow individual cells to be addressed and written via direct tunneling, in both volatile and non-volatile memory cell configurations. The source may be initially implanted. Alternatively, the source may be diffused below the pillars after forming thereof.

Abstract: This invention describes how commercial silicon-on-insulator material can be used to fabricate both wavelength filters and wavelength-selective photodetectors. The silicon-on-insulator substrates have a buried silicon dioxide layer and a thin top silicon layer and are manufactured for high speed electonics applications. However, in this invention, the thin silicon layer is used as the core of a waveguide and the buried silicon dioxide as a lower cladding region. Another cladding layer and a low index waveguide is fabricated on the commercial substrate to form an asymmetric waveguide coupler structure. The added low index waveguide and the original thin silicon layer form the two waveguides of the coupler. Since the the two waveguide materials have very different indices of refraction, they are only phase-matched at one wavelength. Thus for a given thickness of materials, only one wavelength couples between the two waveguides.