摘要:
A method and semiconductor structure that uses a field enhanced region where the oxide thickness is substantially reduced, thereby allowing antifuse programming at burn-in voltages which do not damage the standard CMOS logic. The semiconductor device comprises a substrate that has a raised protrusion terminating at a substantially sharp point, an insulator layer over the raised protrusion sufficiently thin to be breached by a breakdown voltage applied to the sharp point, a region comprised of a material on the insulator over the raised protrusion for becoming electrically coupled to the substrate after the insulator layer is breached by the breakdown voltage, and a contact for supplying the breakdown voltage to the substrate. In a second embodiment, the semiconductor device comprises a substrate having a trough formed in a top surface of the substrate, a relatively thick insulator layer over the top surface of the substrate, a relatively thin insulator layer over the trough that is breached by a breakdown voltage applied to the trough, a region comprised of a material on the relatively thin insulator layer over the trough for becoming electrically coupled to the substrate after the relatively thin insulator layer is breached by the breakdown voltage, and a contact for supplying the breakdown voltage to said substrate.
摘要:
A method and structure for selectively growing epitaxial silicon in a trench formed within a silicon-on-insulator (SOI) structure. The SOI structure includes a buried oxide layer (BOX) on a bulk silicon substrate, and a silicon layer on the BOX. A pad layer is formed on the silicon layer. The pad layer includes a pad nitride (e.g., silicon nitride) on a pad oxide (e.g., silicon dioxide), and the pad oxide has been formed on the silicon layer. A trench is formed by anisotropically etching through the pad layer, the silicon layer, the BOX, and to a depth within the bulk silicon substrate. Insulative spacers are formed on sidewalls of the trench. An epitaxial silicon layer is grown in the trench from a bottom of the trench to above the pad layer. The pad layer and portions of the epitaxial layer are removed (e.g., by chemical mechanical polishing), resulting in a planarized top surface of the epitaxial layer that is about coplanar with a top surface of the silicon layer. Electronic devices may be formed within the epitaxial silicon of the trench. Such electronic devices may include dynamic random access memory (DRAM), bipolar transistors, Complementary Metal Oxide Semiconductor (CMOS) circuits which are sensitive to floating body effects, and devices requiring threshold voltage matching. Semiconductor devices (e.g., field effect transistors) may be coupled to the SOI structure outside the trench.
摘要:
A structure and method for simultaneously forming array structures and support structures on a substrate comprises forming the array structures to have a V-groove, forming the support structures to have a planar surface, and simultaneously forming a first oxide in the V-groove and a second oxide in the planar surface, wherein the first oxide is thicker than the second oxide.
摘要:
A method and structure for selectively growing epitaxial silicon in a trench formed within a silicon-on-insulator (SOI) structure. The SOI structure includes a buried oxide layer (BOX) on a bulk silicon substrate, and a silicon layer on the BOX. A pad layer is formed on the silicon layer. The pad layer includes a pad nitride (e.g., silicon nitride) on a pad oxide (e.g., silicon dioxide), and the pad oxide has been formed on the silicon layer. A trench is formed by anisotropically etching through the pad layer, the silicon layer, the BOX, and to a depth within the bulk silicon substrate. Insulative spacers are formed on sidewalls of the trench. An epitaxial silicon layer is grown in the trench from a bottom of the trench to above the pad layer. The pad layer and portions of the epitaxial layer are removed (e.g., by chemical mechanical polishing), resulting in a planarized top surface of the epitaxial layer that is about coplanar with a top surface of the silicon layer. Electronic devices may be formed within the epitaxial silicon of the trench. Such electronic devices may include dynamic random access memory (DRAM), bipolar transistors, Complementary Metal Oxide Semiconductor (CMOS) circuits which are sensitive to floating body effects, and devices requiring threshold voltage matching. Semiconductor devices (e.g., field effect transistors) may be coupled to the SOI structure outside the trench.
摘要:
A memory cell (8F2 and sub-8F2) formed by: (a) forming a stack of at least four material layers on a surface of a semiconductor substrate, wherein at least two of said material layers of said stack are selectively etchable relative to each other; (b) patternwise etching through said stack to define a critical pattern of remaining stack and spaces where said semiconductor substrate is exposed, said critical pattern defining possible locations for trench capacitors and gate conductors; (c) filling said spaces with a filler material which is selectively etchable relative to a topmost layer of said remaining stack; (d) planarizing the filler material stopping at said topmost layer of said remaining stack; (e) forming trench capacitors in said semiconductor substrate by etching through portions of said filler material and said substrate, wherein said etching removes a portion of said topmost layer of said remaining stack and exposes a portion of a layer of said stack that is next to the topmost layer; (f) planarizing the remaining portion of said stack and filler material to remove the remaining portion of the topmost layer of said stack and the remaining portion of the layer that is next to the topmost layer and thereby exposing a layer of said stack that is second from the topmost layer; (g) replacing at least a portion of either said remaining stack and/or remaining filler material with a placeholder material corresponding to locations for gate conductors; and (h) forming said gate conductors and remaining portions of said transistors, bitlines and wordlines of said memory cell.
摘要:
A simple and low cost ULSI integrated heatsink more efficiently removes heat from a silicon package by integrating the heat sink material into the silicon die, transforming the present two-dimensional art into three dimensions. The fabrication of a high power integrated ULSI package and heatsink begins by fabricating an integrated circuit wafer up to the point of dicing the wafer into individual chips. The front side of the wafer is protected, while the backside of the wafer is exposed. The exposed backside is roughened by chemical and/or mechanical process. Optionally, a gettering process is then performed to remove impurities. The roughened backside is then coated with metal interlayers, preferably aluminum (Al) by chromium (Cr). A layer of copper (Cu) is optionally coated on the metal interlayers. A highly conductive reflowable material, such as solder or gold eutectic, is deposited on the metal interlayers. At this point, the wafer is diced to form chips. The heatsink itself is prepared by first optionally roughening the surface and metalizing the backside of the heatsink with metal interlayer. Next, the chip is thermally attached to the heatsink by reflowing the thermally conductive reflowable material.
摘要:
A simple and low cost ULSI integrated heatsink more efficiently removes heat from a silicon package by integrating the heat sink material into the silicon die, transforming the present two-dimensional art into three dimensions. The fabrication of a high power integrated ULSI package and heatsink begins by fabricating an integrated circuit wafer up to the point of dicing the wafer into individual chips. The front side of the wafer is protected, while the backside of the wafer is exposed. The exposed backside is roughened by chemical and/or mechanical process. Optionally, a gettering process is then performed to remove impurities. The roughened backside is then coated with metal interlayers, preferably aluminum (Al) followed by chromium (Cr). A layer of copper (Cu) is optionally coated on the metal interlayers. A highly conductive reflowable material, such as solder or gold eutectic, is deposited on the metal interlayers. At this point, the wafer is diced to form chips. The heatsink itself is prepared by first optionally roughening the surface and metalizing the backside of the heatsink with metal interlayer. Next, the chip is thermally attached to the heatsink by reflowing the thermally conductive reflowable material.
摘要:
A method of forming a semiconductor device, including providing a substrate having a first insulative layer on a surface of the substrate, and a device layer on a surface of the first insulative layer, forming a spacer around the first insulative layer and the device layer, removing a portion of the substrate adjacent to the first insulative layer in a first region and a non-adjacent second region of the substrate, such that an opening is formed in the first and second regions of the substrate, leaving the substrate adjacent to the first insulative layer in a third region of the substrate, filling the opening within the first and second regions of the substrate, planarizing a surface of the device, and forming a device within the device layer, such that diffusion regions of the device are formed within the device layer above the first and second regions of the substrate, and a channel region of the device is formed above the third region of the substrate.
摘要:
A diode comprises a substrate formed of a first material having a first doping polarity. The substrate has a planar surface and at least one semispherical structure extending from the planar surface. The semispherical structure is formed of the first material. A layer of second material is over the semispherical structure. The second material comprises a second doping polarity opposite the first doping polarity. The layer of second material conforms to the shape of the semispherical structure. A first electrical contact is connected to the substrate, and a second electrical contact is connected to the layer of second material. Additional semiconductor structures are formed by fabricating additional layers over the original layers.
摘要:
A diode comprises a substrate formed of a first material having a first doping polarity. The substrate has a planar surface and at least one semispherical structure extending from the planar surface. The semispherical structure is formed of the first material. A layer of second material is over the semispherical structure. The second material comprises a second doping polarity opposite the first doping polarity. The layer of second material conforms to the shape of the semispherical structure. A first electrical contact is connected to the substrate, and a second electrical contact is connected to the layer of second material. Additional semiconductor structures are formed by fabricating additional layers over the original layers.