Abstract: The present disclosure provides methods and systems for controlling temperature. The method has particular utility in connection with controlling temperature in a deposition process, e.g., in depositing a heat-reflective material via CVD. One exemplary embodiment provides a method that involves monitoring a first temperature outside the deposition chamber and a second temperature inside the deposition chamber. An internal temperature in the deposition chamber can be increased in accordance with a ramp profile by (a) comparing a control temperature to a target temperature, and (b) selectively delivering heat to the deposition chamber in response to a result of the comparison. The target temperature may be determined in accordance with the ramp profile, but the control temperature in one implementation alternates between the first temperature and the second temperature.

Abstract: A nonvolatile memory cell includes a steering element located in series with a storage element. The storage element includes a carbon material and the memory cell includes a rewritable cell having multiple memory levels.

Abstract: The present disclosure provides methods and systems for controlling temperature. The method has particular utility in connection with controlling temperature in a deposition process, e.g., in depositing a heat-reflective material via CVD. One exemplary embodiment provides a method that involves monitoring a first temperature outside the deposition chamber and a second temperature inside the deposition chamber. An internal temperature in the deposition chamber can be increased in accordance with a ramp profile by (a) comparing a control temperature to a target temperature, and (b) selectively delivering heat to the deposition chamber in response to a result of the comparison. The target temperature may be determined in accordance with the ramp profile, but the control temperature in one implementation alternates between the first temperature and the second temperature.

Abstract: A nonvolatile memory cell includes a storage element, the storage element comprising a carbon material, a steering element located in series with the storage element, and a metal silicide layer located adjacent to the carbon material. A method of making a device includes forming a metal silicide over a silicon layer, forming a carbon layer over the metal silicide layer, forming a barrier layer over the carbon layer, and patterning the carbon layer, the metal silicide layer, and the silicon layer to form an array of pillars.

Abstract: In a first aspect, a method of forming a memory cell is provided that includes (1) forming a metal-insulator-metal (“MIM”) stack above a substrate, the MIM stack including a carbon-based switching material having a resistivity of at least 1×104 ohm-cm; and (2) forming a steering element coupled to the MIM stack. Numerous other aspects are provided.

Abstract: Some embodiments include methods in which insulative material is simultaneously deposited across both a front side of a semiconductor substrate, and across a back side of the substrate. Subsequently, openings may be etched through the insulative material across the front side, and the substrate may then be dipped within a plating bath to grow conductive contact regions within the openings. The insulative material across the back side may protect the back side from being plated during the growth of the conductive contact regions over the front side. In some embodiments, plasma-enhanced atomic layer deposition may be utilized to for the deposition, and may be conducted at a temperature suitable to anneal passivation materials so that such annealing occurs simultaneously with the plasma-enhanced atomic layer deposition.

Abstract: A method of making a non-volatile memory device includes forming a first electrode, forming a steering element, forming at least one feature, forming a carbon resistivity switching material on at least one sidewall of the at least one feature such that the carbon resistivity switching material electrically contacts the steering element, and forming a second electrode.

Abstract: A self-aligned fabrication process for three-dimensional non-volatile memory is disclosed. A double etch process forms conductors at a given level in self-alignment with memory pillars both underlying and overlying the conductors. Forming the conductors in this manner can include etching a first conductor layer using a first repeating pattern in a given direction to form a first portion of the conductors. Etching with the first pattern also defines two opposing sidewalls of an underlying pillar structure, thereby self-aligning the conductors with the pillars. After etching, a second conductor layer is deposited followed by a semiconductor layer stack. Etching with a second pattern that repeats in the same direction as the first pattern is performed, thereby forming a second portion of the conductors that is self-aligned with overlying layer stack lines. These layer stack lines are then etched orthogonally to define a second set of pillars overlying the conductors.

Abstract: Methods in accordance with this invention form a microelectronic structure by forming a carbon nano-tube (“CNT”) layer, and forming a carbon layer (“carbon liner”) above the CNT layer, wherein the carbon liner comprises: (1) a first portion disposed above and in contact with the CNT layer; and/or (2) a second portion disposed in and/or around one or more carbon nano-tubes in the CNT layer. Numerous other aspects are provided.

Abstract: Some embodiments include methods in which insulative material is simultaneously deposited across both a front side of a semiconductor substrate, and across a back side of the substrate. Subsequently, openings may be etched through the insulative material across the front side, and the substrate may then be dipped within a plating bath to grow conductive contact regions within the openings. The insulative material across the back side may protect the back side from being plated during the growth of the conductive contact regions over the front side. In some embodiments, plasma-enhanced atomic layer deposition may be utilized to for the deposition, and may be conducted at a temperature suitable to anneal passivation materials so that such annealing occurs simultaneously with the plasma-enhanced atomic layer deposition.

Abstract: A metal-insulator diode is disclosed. In one aspect, the metal-insulator diode comprises first and second electrode and first and second insulators arraigned as follows. An insulating region has a trench formed therein. The trench has a bottom and side walls. The first electrode, which comprises a first metal, is on the side walls and over the bottom of the trench. A first insulator has a first interface with the first electrode. At least a portion of the first insulator is within the trench. A second insulator has a second interface with the first insulator. At least a portion of the second insulator is within the trench. The second electrode, which comprises a second metal, is in contact with the second insulator. The second electrode at least partially fills the trench.

Abstract: Methods of forming memory cells are disclosed which include forming a pillar above a substrate, the pillar including a steering element and a memory element, and performing one or more etches vertically through the pillar to form multiple memory cells. Memory cells formed from such methods, as well as numerous other aspects are also disclosed.

Abstract: Methods of forming memory cells are disclosed which include forming a pillar above a substrate, the pillar including a steering element and a memory element, and performing one or more etches vertically through the memory element, but not the steering element, to form multiple memory cells that share a single steering element. Memory cells formed from such methods, as well as numerous other aspects are also disclosed.

Abstract: Methods of forming memory devices, and memory devices formed in accordance with such methods, are provided, the methods including forming a via above a first conductive layer, forming a nonconformal carbon-based resistivity-switchable material layer in the via and coupled to the first conductive layer; and forming a second conductive layer in the via, above and coupled to the nonconformal carbon-based resistivity-switchable material layer. Numerous other aspects are provided.

Abstract: Systems for depositing material onto workpieces in reaction chambers and methods for removing byproducts from reaction chambers are disclosed herein. In one embodiment, the system includes a gas phase reaction chamber, a first exhaust line coupled to the reaction chamber, first and second traps each in fluid communication with the first exhaust line, and a vacuum pump coupled to the first exhaust line to remove gases from the reaction chamber. The first and second traps are operable independently to individually and/or jointly collect byproducts from the reaction chamber. It is emphasized that this Abstract is provided to comply with the rules requiring an abstract. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: In a first aspect, a memory cell is provided that includes (1) a first conductor; (2) a reversible resistance-switching element formed above the first conductor including (a) a carbon-based resistivity switching material; and (b) a carbon-based interface layer coupled to the carbon-based resistivity switching material; (3) a steering element formed above the first conductor; and (4) a second conductor formed above the reversible resistance-switching element and the steering element. Numerous other aspects are provided.

Abstract: Memory devices including a carbon-based resistivity-switchable material, and methods of forming such memory devices are provided, the methods including introducing a processing gas into a processing chamber, wherein the processing gas includes a hydrocarbon compound and a carrier gas, and generating a plasma of the processing gas to deposit a layer of the carbon-based switchable material on a substrate within the processing chamber. Numerous additional aspects are provided.

Abstract: Disclosed is a container capacitor structure and method of constructing it. An etch mask and etch are used to expose portions of an exterior surface of electrode (“bottom electrodes”) of the container capacitor structure. The etch provides a recess between proximal pairs of container capacitor structures, which recess is available for forming additional capacitance. Accordingly, a capacitor dielectric and a top electrode are formed on and adjacent to, respectively, both an interior surface and portions of the exterior surface of the first electrode. Advantageously, surface area common to both the first electrode and second electrodes is increased over using only the interior surface, which provides additional capacitance without a decrease in spacing for clearing portions of the capacitor dielectric and the second electrode away from a contact hole location.

Abstract: Structures and methods for making a semiconductor structure are discussed. The semiconductor structure includes a rough surface having protrusions formed from an undoped silicon film. If the semiconductor structure is a capacitor, the protrusions help to increase the capacitance of the capacitor. The semiconductor structure also includes a relatively smooth surface abutting the rough surface, wherein the relatively smooth surface is formed from a polycrystalline material.

Abstract: Container capacitor structure and method of construction. An etch mask and etch are used to expose portions of an exterior surface of an electrode (“bottom electrodes”) of the structure. The etch provides a recess between proximal pairs of container capacitor structures, which is available for forming additional capacitance. A capacitor dielectric and top electrode are formed on and adjacent to, respectively, both an interior surface and portions of the exterior surface of the first electrode. Surface area common to both the first electrode and second electrodes is increased over using only the interior surface, providing additional capacitance without decreasing spacing for clearing portions of the capacitor dielectric and the second electrode away from a contact hole location. Clearing of the capacitor dielectric and the second electrode portions may be done at an upper location of a substrate assembly in contrast to clearing at a bottom location of a contact via.