Abstract: A method of operating a nonvolatile memory cell includes providing the nonvolatile memory cell comprising a diode which is fabricated in a first resistivity, unprogrammed state, and applying a forward bias to the diode having a magnitude greater than a minimum voltage required for programming the diode to switch the diode to a second resistivity, programmed state. The second resistivity state is lower than the first resistivity state.

Abstract: A photovoltaic assembly comprises a thin semiconductor lamina and a receiver element, where the receiver element serves as a superstrate in the completed device. The photovoltaic assembly includes a photovoltaic cell. The photovoltaic cell is a back-contact cell; photocurrent passes into and out of the back surface of the cell, but does not pass through the light-facing surface. The lamina is typically substantially crystalline and has a thickness less than about 100 microns, in some embodiments 10 microns or less.

Abstract: A photovoltaic cell comprising a thin semiconductor lamina is described; the lamina is formed by cleaving from a donor wafer while the wafer is bonded to a receiver element which provides mechanical support. Thus fabrication steps performed following cleaving are advantageously performed at temperatures that will not damage the receiver element. By fabricating a cell comprising an MIS-type tunnel diode, rather than a conventional p-n diode, a high-temperature doping step may be avoided.

Abstract: A substantially planar surface coexposes conductive or semiconductor features and a dielectric etch stop material. A second dielectric material, different from the dielectric etch stop material, is deposited on the substantially planar surface. A selective etch etches a hole or trench in the second dielectric material, so that the etch stops on the conductive or semiconductor feature and the dielectric etch stop material. In a preferred embodiment the substantially planar surface is formed by filling gaps between the conductive or semiconductor features with a first dielectric such as oxide, recessing the oxide, filling with a second dielectric such as nitride, then planarizing to coexpose the nitride and the conductive or semiconductor features.

Abstract: A method is described for forming a thin film transistor having its current-switching region in polycrystalline semiconductor material which has been crystallized in contact with titanium silicide, titanium silicide-germanide, or titanium germanide. The titanium silicide, titanium silicide-germanide, or titanium germanide is formed having feature size no more than 0.25 micron in the smallest dimension. The small feature size tends to inhibit the phase transformation from C49 to C54 phase titanium silicide. The C49 phase of titanium silicide has a very close lattice match to silicon, and thus provides a crystallization template for the silicon as it forms, allowing formation of large-grain, low-defect silicon. Titanium does not tend to migrate through the silicon during crystallization, limiting the danger of metal contamination. In preferred embodiments, the transistors thus formed may be, for example, field-effect transistors or bipolar junction transistors.

Abstract: A method of making a semiconductor device includes forming at least one device layer over a substrate, forming at least two spaced apart features over the at least one device layer, forming sidewall spacers on the at least two features, selectively removing the spaced apart features, filling a space between a first sidewall spacer and a second sidewall spacer with a filler feature, selectively removing the sidewall spacers to leave a plurality of the filler features spaced apart from each other, and etching the at least one device layer using the filler feature as a mask.

Abstract: A nonvolatile memory device includes a semiconductor diode steering element, and a semiconductor read/write switching element.

Abstract: A method of making a semiconductor device includes forming at least one device layer over a substrate, forming at least two spaced apart features over the at least one device layer, forming sidewall spacers on the at least two features, filling a space between a first sidewall spacer on a first feature and a second sidewall spacer on a second feature with a filler feature, selectively removing the sidewall spacers to leave the first feature, the filler feature and the second feature spaced apart from each other, and etching the at least one device layer using the first feature, the filler feature and the second feature as a mask.

Abstract: A method of making a pillar device includes providing an insulating layer having an opening, and selectively depositing germanium or germanium rich silicon germanium semiconductor material into the opening to form the pillar device.

Abstract: A nonvolatile memory device includes a plurality of nonvolatile memory cells arranged in a substantially hexagonal pattern. The nonvolatile memory cells may be pillar shaped non-volatile memory cells which can be patterned using triple or quadruple exposure lithography or by using a self-assembling layer.

Abstract: In aspects of the present invention, a lamina is formed having opposing first and second surfaces. Heavily doped contact regions extend from the first surface to the second surface. Generally the lamina is formed by affixing a semiconductor donor body to a receiver element, then cleaving the lamina from the semiconductor donor body wherein the lamina remains affixed to the receiver element. In the present invention, the heavily doped contact regions are formed by doping the semiconductor donor body before cleaving of the lamina. A photovoltaic cell comprising the lamina is then fabricated. By forming the heavily doped contact regions before bonding to the receiver element and cleaving, post-bonding high-temperature steps can be avoided, which may be advantageous.

Abstract: In aspects of the present invention, a method is disclosed to form a lamina having opposing first and second surfaces. Heavily doped contact regions extend from the first surface to the second surface. Generally the lamina is formed by affixing a semiconductor donor body to a receiver element, then cleaving the lamina from the semiconductor donor body wherein the lamina remains affixed to the receiver element. In the present invention, the heavily doped contact regions are formed by doping the semiconductor donor body before cleaving of the lamina. A photovoltaic cell comprising the lamina is then fabricated. By forming the heavily doped contact regions before bonding to the receiver element and cleaving, post-bonding high-temperature steps can be avoided, which may be advantageous.

Abstract: A photovoltaic device is disclosed herein that, in various aspects, includes a conductive layer, and a substantially crystalline lamina with a first surface oriented toward the conductive layer and a second surface oriented away from the conductive layer. The lamina thickness is within the range between about 0.2 microns and about 50 microns. An aperture passes through the lamina from the first surface to the second surface. A connector in electrical communication with the conductive layer is disposed through the aperture. Methods of manufacture of the photovoltaic devise are also disclosed.

Abstract: A method of programming a nonvolatile memory array including a plurality of nonvolatile memory cells, a plurality of bit lines, and a plurality of word lines, wherein each memory cell comprises a diode, or a diode and a resistivity switching element is disclosed. The method includes both bias programming the memory cells of the device.

Abstract: A photovoltaic cell can be formed from a thin semiconductor lamina cleaved from a substantially crystalline wafer. Shunts may inadvertently be formed through such a lamina, compromising device performance. By physically severing the lamina into a plurality of segments, the segments of the lamina preferably electrically connected in series, loss of efficiency due to shunt formation may be substantially reduced. In some embodiments, adjacent laminae are connected in series into strings, and the strings are connected in parallel to compensate for the reduction in current caused by severing the lamina into segments.

Abstract: Fabrication of a photovoltaic cell comprising a thin semiconductor lamina may require additional processing after the semiconductor lamina is bonded to a receiver. To minimize high-temperature steps after bonding, the p?n junction is formed at the back of the cell, at the bonded surface. In some embodiments, the front surface of the semiconductor lamina is not doped or is locally doped using low-temperature methods. The base resistivity of the photovoltaic cell may be reduced, allowing a front surface field to be reduced or omitted.

Abstract: A photovoltaic cell can be formed from a thin semiconductor lamina cleaved from a substantially crystalline wafer. Shunts may inadvertently be formed through such a lamina, compromising device performance. By physically severing the lamina into a plurality of segments, the segments of the lamina preferably electrically connected in series, loss of efficiency due to shunt formation may be substantially reduced. In some embodiments, adjacent laminae are connected in series into strings, and the strings are connected in parallel to compensate for the reduction in current caused by severing the lamina into segments.

Abstract: A very thin photovoltaic cell is formed by implanting gas ions below the surface of a donor body such as a semiconductor wafer. Ion implantation defines a cleave plane, and a subsequent step exfoliates a thin lamina from the wafer at the cleave plane. A photovoltaic cell, or all or a portion of the base or emitter of a photovoltaic cell, is formed within the lamina. In preferred embodiments, the wafer is affixed to a receiver before the cleaving step. Electrical contact can be formed to both surfaces of the lamina, or to one surface only.

Abstract: An integrated circuit including vertically oriented diode structures between conductors and methods of fabricating the same are provided. Two-terminal devices such as passive element memory cells can include a diode steering element in series with an antifuse and/or other state change element. The devices are formed using pillar structures at the intersections of upper and lower sets of conductors. The height of the pillar structures are reduced by forming part of the diode for each pillar in a rail stack with one of the conductors. A diode in one embodiment can include a first diode component of a first conductivity type and a second diode component of a second conductivity type. A portion of one of the diode components is divided into first and second portions with one on the portions being formed in the rail stack where it is shared with other diodes formed using pillars at the rail stack.

Abstract: A novel surface texturing provides improved light-trapping characteristics for photovoltaic cells. The surface is asymmetric and includes shallow slopes at between about 5 and about 30 degrees from horizontal as well as steeper slopes at about 70 degrees or more from horizontal. It is advantageously used as either the front or back surface of a thin semiconductor lamina, for example between about 1 and about 20 microns thick, which comprises at least the base or emitter of a photovoltaic cell. In embodiments of the present invention, the shallow slopes are formed using imprint photolithography.