Abstract: Conventional fabrication of sidewall oxide around an ONO-type memory cell stack usually produces Bird's Beak because prior to the fabrication, there is an exposed sidewall of the ONO-type memory cell stack that exposes side parts of a plurality of material layers respectively composed of different materials. Certain materials in the stack such as silicon nitrides are more difficult to oxidize than other materials in the stack such polysilicon. As a result oxidation does not proceed uniformly along the multi-layered height of the sidewall. The present disclosure shows how radical-based fabrication of sidewall dielectric can help to reduce the Bird's Beak formation. More specifically, it is indicated that short-lived oxidizing agents (e.g.

Abstract: A method for preparing a memory structure comprises the steps of forming a plurality of line-shaped blocks on a dielectric structure of a substrate, and forming a first etching mask exposing a sidewall of the line-shaped blocks. A portion of the line-shaped blocks is removed incorporating the first etching mask to reduce the width of the line-shaped blocks to form a second etching mask including a plurality of first blocks and second blocks arranged in an interlaced manner. Subsequently, a portion of the dielectric structure not covered by the second etching mask is removed to form a plurality of openings in the dielectric structure, and a conductive plug is formed in each of the openings. The plurality of openings includes first openings positioned between the first blocks and second openings positioned between the second blocks, and the first opening and the second opening extend to opposite sides of an active area.

Abstract: A reduced area dynamic random access memory (DRAM) cell and method for fabricating the same wherein the cell occupies an area smaller than one photolithography pitch by two photolithography pitches through the formation of sidewall spacers along a first pattern to define a first portion of the active region of the memory cell and a second orthogonally oriented pattern to define a second portion of the active region of the memory cell thereby creating a ladder shaped active region for a column of the memory cells.

Abstract: A contact via to a surface of a semiconductor material is provided, the contact via having a sidewall which is produced by anisotropically etching a dielectric layer which is placed on via openings. A protective layer is provided on the surface of the semiconductor material. To protect the substrate, an initial etch through an interlayer dielectric is performed to create an initial via which extends toward, but not into the substrate. At least a portion of the protective layer is retained on the substrate. In another step, the final contact via is created. During this step the protective layer is penetrated to open a via to the surface of the semiconductor material.

Abstract: A method for preparing a memory structure comprises the steps of forming a plurality of line-shaped blocks on a dielectric structure of a substrate, and forming a first etching mask exposing a sidewall of the line-shaped blocks. A portion of the line-shaped blocks is removed incorporating the first etching mask to reduce the width of the line-shaped blocks to form a second etching mask including a plurality of first blocks and second blocks arranged in an interlaced manner. Subsequently, a portion of the dielectric structure not covered by the second etching mask is removed to form a plurality of openings in the dielectric structure, and a conductive plug is formed in each of the openings. The plurality of openings includes first openings positioned between the first blocks and second openings positioned between the second blocks, and the first opening and the second opening extend to opposite sides of an active area.

Abstract: A memory structure comprises a semiconductor substrate, an active are positioned in the semiconductor substrate, a plurality of doped regions positioned in the semiconductor substrate, a first conductive plug connecting a bit line and one of the doped regions and a second conductive plug connecting a capacitor and another one of doped regions. The first conductive plug includes a first block positioned in the active area and a second block positioned at a first side of the active area, and the bit line electrically connects the second block. The second conductive plug includes a third block positioned in the active area and a fourth block positioned at a second side of the active area, and the capacitor electrically connects the fourth block. The first side of the active area is opposite to the second side of the active area.

Abstract: A method and apparatus are disclosed for reducing the concentration of chlorine and/or other bound contaminants within a semiconductor oxide composition that is formed by chemical vapor deposition (CVD) using a semiconductor-element-providing reactant such as dichlorosilane (DCS) and an oxygen-providing reactant such as N2O. In one embodiment, a DCS-HTO film is annealed by heating N2O gas to a temperature in the range of about 825° C. to about 950° C. so as to trigger exothermic decomposition of the N2O gas and flowing the heated gas across the DCS-HTO film so that disassociated atomic oxygen radicals within the heated N2O gas can transfer disassociating energy to chlorine atoms bound within the DCS-HTO film and so that the atomic oxygen radicals can fill oxygen vacancies within the semiconductor-oxide matrix of DCS-HTO film. An improved ONO structure may be formed with the annealed DCS-HTO film for use in floating gate or other memory applications.

Abstract: Nonvolatile memory wordlines (160) are formed as sidewall spacers on sidewalls of control gate structures (280). Each control gate structure may contain floating and control gates (120, 140), or some other elements. Pedestals (340) are formed adjacent to the control gate structures before the conductive layer (160) for the wordlines is deposited. The pedestals will facilitate formation of the contact openings (330.1) that will be etched in an overlying dielectric (310) to form contacts to the wordlines. The pedestals can be dummy structures. A pedestal can physically contact two wordlines.

Abstract: Conventional fabrication of top oxide in an ONO-type memory cell stack usually produces Bird's Beak. Certain materials in the stack such as silicon nitrides are relatively difficult to oxidize. As a result oxidation does not proceed uniformly along the multi-layered height of the ONO-type stack. The present disclosure shows how radical-based fabrication of top-oxide of an ONO stack (i.e. by ISSG method) can help to reduce formation of Bird's Beak. More specifically, it is indicated that short-lived oxidizing agents (e.g., atomic oxygen) are able to better oxidize difficult to oxidize materials such as silicon nitride and the it is indicated that the short-lived oxidizing agents alternatively or additionally do not diffuse deeply through already oxidized layers of the ONO stack such as the lower silicon oxide layer. As a result, a more uniform top oxide dielectric can be fabricated with more uniform breakdown voltages along its height.

Abstract: Dielectric regions (210) are formed on a semiconductor substrate between active areas of nonvolatile memory cells. The top portions of the dielectric region sidewalls are etched to recess the top portions laterally away from the active areas. Then a conductive layer is deposited to form the floating gates (410). The recessed portions of the dielectric sidewalls allow the floating gates to be wider at the top. The gate coupling ratio is increased as a result. Other features are also provided.

Abstract: Dielectric regions (210) are formed on a semiconductor substrate between active areas of nonvolatile memory cells. The top portions of the dielectric region sidewalls are etched to recess the top portions laterally away from the active areas. Then a conductive layer is deposited to form the floating gates (410). The recessed portions of the dielectric sidewalls allow the floating gates to be wider at the top. The gate coupling ratio is increased as a result. Other features are also provided.

Abstract: The present invention provides a method for preventing doped boron in a dielectric layer from diffusing into a substrate. First, at least one gate is formed on a periphery circuit area and a memory array area of a substrate, respectively, wherein the pattern density in the memory array area is higher than that in the periphery circuit area. Then, a barrier layer is formed on the memory array area and the periphery circuit area, and an undoped oxide barrier is formed on the periphery circuit area. Finally, a silicate glass containing boron is deposited on the memory array area and the periphery circuit area.

Abstract: The present invention relates to a semiconductor device comprising at least one gate located in each of a memory array area and a periphery circuit area of a substrate, respectively, wherein the pattern density in the memory array area is higher than that in the periphery circuit area. The semiconductor device also comprises a barrier layer, which is located in the memory array area and the periphery circuit area, an undoped oxide barrier, which is located on the barrier layer in the periphery circuit area, and a boron-containing silicate glass, which is located on the barrier layer in the memory array area and on the undoped oxide barrier in the periphery circuit area.

Abstract: A reduced area dynamic random access memory (DRAM) cell and method for fabricating the same wherein the cell occupies an area smaller than one photolithography pitch by two photolithography pitches through the formation of sidewall spacers along a first pattern to define a first portion of the active region of the memory cell and a second orthogonally oriented pattern to define a second portion of the active region of the memory cell thereby creating a ladder shaped active region for a column of the memory cells.

Abstract: A method of fabricating a shallow trench isolation structure is provided. A substrate having a patterned pad layer is provided. A part of the substrate is removed by using the patterned pad layer as a mask and a trench is thus formed in the substrate. A first insulation layer is formed on the substrate, the patterned pad layer and the trench. A second insulation layer is formed on the first insulation layer and partially fills into the trench. A third insulation layer is formed on the substrate and fills in the trench. The third insulation layer on the patterned pad layer and the patterned pad layer are removed subsequently.

Abstract: A method and structure are provided with reduced gate wrap around to advantageously control for threshold voltage and increase stability in semiconductor devices. A spacer is provided aligned to field dielectric layers to protect the dielectric layers during subsequent etch processes. The spacer is then removed prior to subsequently forming a part of a gate oxide layer and a gate conductor layer. Advantageously, the spacer protects the corner area o the field dielectric and also allows for enhanced thickness of the gate oxide near the corners.

Abstract: A method and apparatus are disclosed for reducing the concentration of chlorine and/or other bound contaminants within a semiconductor oxide composition that is formed by chemical vapor deposition (CVD) using a semiconductor-element-providing reactant such as dichlorosilane (DCS) and an oxygen-providing reactant such as N2O. In one embodiment, a DCS-HTO film is annealed by heating N2O gas to a temperature in the range of about 825° C. to about 950 ° C. so as to trigger exothermic decomposition of the N2O gas and flowing the heated gas across the DCS-HTO film so that disassociated atomic oxygen radicals within the heated N2O gas can transfer disassociating energy to chlorine atoms bound within the DCS-HTO film and so that the atomic oxygen radicals can fill oxygen vacancies within the semiconductor-oxide matrix of DCS-HTO film. An improved ONO structure may be formed with the annealed DCS-HTO film for use in floating gate or other memory applications.

Abstract: In integrated circuit fabrication, an etch is used that has a lateral component. For example, the etch may be isotropic. Before the isotropic etch of a layer (160), another etch of the same layer is performed. This other etch can be anisotropic. This etch attacks a portion (160X2) of the layer adjacent to the feature to be formed by the isotropic etch. That portion is entirely or partially removed by the anisotropic etch. Then the isotropic etch mask (420) is formed to extend beyond the feature over the location of the portion subjected to the anisotropic etch. If that portion was removed entirely, then the isotropic etch mask may completely seal off the feature to be formed on the side of that portion, so the lateral etching will not occur. If that portion was removed only partially, then the lateral undercut will be impeded because the passage to the feature under the isotropic etch mask will be narrowed.

Abstract: A method and apparatus are disclosed for reducing the concentration of chlorine and/or other bound contaminants within a semiconductor oxide composition that is formed by chemical vapor deposition (CVD) using a semiconductor-element-providing reactant such as dichlorosilane (DCS) and an oxygen-providing reactant such as N2O. In one embodiment, a DCS-HTO film is annealed by heating N2O gas to a temperature in the range of about 825° C. to about 950° C. so as to trigger exothermic decomposition of the N2O gas and flowing the heated gas across the DCS-HTO film so that disassociated atomic oxygen radicals within the heated N2O gas can transfer disassociating energy to chlorine atoms bound within the DCS-HTO film and so that the atomic oxygen radicals can fill oxygen vacancies within the semiconductor-oxide matrix of DCS-HTO film. An improved ONO structure may be formed with the annealed DCS-HTO film for use in floating gate or other memory applications.

Abstract: In integrated circuit fabrication, an etch is used that has a lateral component. For example, the etch may be isotropic. Before the isotropic etch of a layer (160), another etch of the same layer is performed. This other etch can be anisotropic. This etch attacks a portion (160X2) of the layer adjacent to the feature to be formed by the isotropic etch. That portion is entirely or partially removed by the anisotropic etch. Then the isotropic etch mask (420) is formed to extend beyond the feature over the location of the portion subjected to the anisotropic etch. If that portion was removed entirely, then the isotropic etch mask may completely seal off the feature to be formed on the side of that portion, so the lateral etching will not occur. If that portion was removed only partially, then the lateral undercut will be impeded because the passage to the feature under the isotropic etch mask will be narrowed.