Abstract: A sub-lithographic device, and a method of fabricating the device, is provided. The method includes determining a lithographic size constraint, and determining size and position of sub-lithographic components of the device. A resist layer is deposited on a substrate, and a mask is positioned over the substrate. The mask includes an aperture corresponding to a first region of the resist layer. After positioning the mask, the resist layer is partially exposed to a radiant energy. The mask is adjusted such that the aperture corresponds to a second region of the resist layer. The overlap of the first region and the second region corresponds to the position of a component of the device. The resist layer is partially exposed again to the radiant energy. An opening is formed in the resist layer by removing fully exposed portion of the resist layer. Subsequently, material for the component is deposited within the opening.

Abstract: A system and method of fabricating a plurality of devices with reduced isolation regions there between, is provided. The method includes obtaining a substrate with a dielectric layer and a resist layer stacked thereupon. The resist layer has a sensitivity to a radiant energy and has a first exposure time. The method also includes identifying a plurality of device locations on the substrate corresponding to the plurality of devices. The plurality of device locations are separated from one another by a plurality of sub-lithographic isolation regions such that the plurality of devices is electrically insulated from one another. The method includes fabricating the plurality of isolation regions by partially exposing the resist layer to the radiant energy a plurality of times, removing fully exposed portions of the resist layer, and creating sub-lithographic isolation regions by depositing a dielectric material in the openings in the substrate.

Abstract: The various implementations described herein include methods, devices, and systems for performing operations on memory devices. In one aspect, a memory device a magnetic memory component and a current selector component coupled to the magnetic memory component. The current selector component includes a first transistor having a first gate with a corresponding first threshold voltage. The first transistor comprises a charge storage layer configured to selectively store charge so as to adjust a current through the first transistor. The memory device further includes control circuitry configured to determine a bit error rate of the magnetic memory component and adjust a charge stored in the charge storage layer based on the determined bit error rate.

Abstract: A device having two transistors with dual thresholds, and a method of fabricating the device, including fabricating a silicide source, a conductive layer, and contacts to a plurality of layers of the device, is provided. The device has a core and a plurality of layers that surround the core in succession, including a first layer, a second layer, a third layer, and a fourth layer. The device further comprises a first input terminal coupled to the core, the first input terminal being configured to receive a first voltage and a second input terminal coupled to the fourth layer, the second input terminal being configured to receive a second voltage. The device comprises a common source terminal coupled to the core and the fourth layer. A memory device, such as an MTJ, may be coupled to the device.

Abstract: An annular device is provided. The annular device includes a first transistor including a first input terminal and a second transistor including a second input terminal. The first input terminal and the second input terminal extend radially outward from the annular device, and wherein the first input terminal is aligned with the second input terminal.

Abstract: A method for forming an array of very small pillar structures having a very small feature size that is smaller than the resolution limit of photolithographic process available for patterning such structures. The method involves forming an array of silicon pillar structures over a layer of material that will ultimately form the pillar structures. The array of silicon pillar structures is repeatedly oxidized to form a layer of silicon oxide at an outer surface of the silicon pillar structures and then etched to remove the outer layer of oxide, thereby reducing the features size (i.e. diameter) of the silicon pillar structure. A final oxidation process entirely oxidizes the remaining silicon pillar structures, leaving an array of small silicon oxide pillar structures that can be used as a mask for patterning underlying layers, including the underlying pillar material. The process is especially useful for forming an array of magnetic memory pillars.

Abstract: A method for forming an array of very small pillar structures having a very small feature size that is smaller than the resolution limit of photolithographic process available for patterning such structures. The method involves forming an array of silicon pillar structures over a layer of material that will ultimately form the pillar structures. The array of silicon pillar structures is repeatedly oxidized to form a layer of silicon oxide at an outer surface of the silicon pillar structures and then etched to remove the outer layer of oxide, thereby reducing the features size (i.e. diameter) of the silicon pillar structure. A final oxidation process entirely oxidizes the remaining silicon pillar structures, leaving an array of small silicon oxide pillar structures that can be used as a mask for patterning underlying layers, including the underlying pillar material. The process is especially useful for forming an array of magnetic memory pillars.

Abstract: The various implementations described herein include methods, devices, and systems for performing operations on memory devices. In one aspect, a memory device includes: (1) a first charge storage device having a first gate with a corresponding first threshold voltage, the first charge storage device configured to store charge corresponding to one or more first bits; and (2) a second charge storage device having a second gate with a corresponding second threshold voltage, distinct from the first threshold voltage, the second charge storage device configured to store charge corresponding to one or more second bits; where the second charge storage device is coupled in parallel with the first charge storage device.

Abstract: A magnetic device, according to one approach, includes: a plurality of perpendicular magnetic tunnel junction (p-MTJ) cells, each p-MTJ cell having a transistor and a magnetic tunnel junction (MTJ) sensor. Moreover, each of the transistors includes a drain terminal, a source terminal, and a gate terminal. The magnetic device also includes: a first common word line coupled to the gate terminal of each transistor in a first subset of the plurality of p-MTJ cells, a first common bit line coupled to a first end of each MTJ sensor in a second subset of the plurality of p-MTJ cells, and a first common source line coupled to the drain terminal of each transistor in the first subset. A second end of each of the MTJ sensors in the second subset is coupled to the source terminal of each respective transistor in the second subset.

Abstract: An annular device is provided. The annular device includes a first transistor including a first input terminal and a second transistor including a second input terminal. The first input terminal and the second input terminal extend radially outward from the annular device, and wherein the first input terminal is aligned with the second input terminal.

Abstract: A switching device, according to one embodiment, includes: a cylindrical pillar gate contact, an annular cylindrical channel which encircles a portion of the cylindrical pillar gate contact, an annular cylindrical oxide layer which encircles a portion of the annular cylindrical channel, and a source contact tab which encircles a portion of the annular cylindrical channel toward a first end of the annular cylindrical channel. Other systems are also described in additional embodiments herein which provide various different switching devices having improved components including improved annular cylindrical channel structures, improved source contacts, and/or improved cylindrical pillar gate contacts. These improved systems and components thereof may be implemented in vertical annular transistor structures in comparison to conventional surface transistor structures.

Abstract: The various implementations described herein include methods, devices, and systems for performing operations on memory devices. In one aspect, a memory device a magnetic memory component and a current selector component coupled to the magnetic memory component. The current selector component includes a first transistor having a first gate with a corresponding first threshold voltage. The first transistor comprises a charge storage layer configured to selectively store charge so as to adjust a current through the first transistor. The memory device further includes control circuitry configured to determine a bit error rate of the magnetic memory component and adjust a charge stored in the charge storage layer based on the determined bit error rate.

Abstract: A method, according to one embodiment, includes: forming an annular cylindrical channel from a single block of electrically conductive material; forming an oxide layer over exposed surfaces of the annular cylindrical channel and exposed surfaces of the block of electrically conductive material; removing a portion of the oxide layer from an exterior base of the annular cylindrical channel, thereby forming a source contact recess which surrounds the base of the annular cylindrical channel; ion-implanting the exposed electrically conductive material substrate at a base of the source contact recess; and depositing a silicide material in the source contact recess, thereby forming a source contact tab.

Abstract: The various implementations described herein include methods, devices, and systems for performing operations on memory devices. In one aspect, a memory device includes: (1) a first charge storage device having a first gate with a corresponding first threshold voltage, the first charge storage device configured to store charge corresponding to one or more first bits; and (2) a second charge storage device having a second gate with a corresponding second threshold voltage, distinct from the first threshold voltage, the second charge storage device configured to store charge corresponding to one or more second bits; where the second charge storage device is coupled in parallel with the first charge storage device.

Abstract: A device having two transistors with dual thresholds, and a method of fabricating the device, including fabricating a silicide source, a conductive layer, and contacts to a plurality of layers of the device, is provided. The device has a core and a plurality of layers that surround the core in succession, including a first layer, a second layer, a third layer, and a fourth layer. The device further comprises a first input terminal coupled to the core, the first input terminal being configured to receive a first voltage and a second input terminal coupled to the fourth layer, the second input terminal being configured to receive a second voltage. The device comprises a common source terminal coupled to the core and the fourth layer. A memory device, such as an MTJ, may be coupled to the device.

Abstract: A switching device, according to one embodiment, includes: a cylindrical pillar; an annular cylindrical oxide layer which encircles a portion of the cylindrical pillar; an annular cylindrical gate contact which encircles a portion of the annular cylindrical oxide layer; and a source contact which encircles a portion of the cylindrical pillar toward a first end of the cylindrical pillar. Other systems are also described in additional embodiments herein which provide various different switching devices having improved components including improved cylindrical gate contacts, improved source contacts, and/or improved drain contacts. These improved systems and components thereof may be implemented in vertical transistor structures which also include the aforementioned cylindrical pillar and cylindrical gate contact in comparison to conventional surface transistor structures.

Abstract: A method of forming a cylindrical vertical transistor; the method, according to one embodiment, includes: forming a cylindrical pillar from a single block of silicon, forming an oxide layer over an exterior of the cylindrical pillar and exposed surfaces of the block of silicon, coating the oxide layer with a spin-on-glass (SOG), depositing a source mask over a majority of the SOG coating, and removing a portion of the SOG coating and underlying oxide layer, where the portion removed is defined by the source mask. Other systems and methods are also described in additional embodiments herein which provide various different improved processes of forming the cylindrical gate contacts, the source contacts, and/or the drain contacts for vertical transistor structures which also include the aforementioned cylindrical pillar channel structures and cylindrical gate in comparison to conventional surface transistor structures.

Abstract: A method, according to one embodiment, includes: forming an annular cylindrical channel from a single block of electrically conductive material; forming an oxide layer over exposed surfaces of the annular cylindrical channel and exposed surfaces of the block of electrically conductive material; removing a portion of the oxide layer from an exterior base of the annular cylindrical channel, thereby forming a source contact recess which surrounds the base of the annular cylindrical channel; ion-implanting the exposed electrically conductive material substrate at a base of the source contact recess; and depositing a silicide material in the source contact recess, thereby forming a source contact tab.

Abstract: A switching device, according to one embodiment, includes: a cylindrical pillar; an annular cylindrical oxide layer which encircles a portion of the cylindrical pillar; an annular cylindrical gate contact which encircles a portion of the annular cylindrical oxide layer; and a source contact which encircles a portion of the cylindrical pillar toward a first end of the cylindrical pillar. Other systems are also described in additional embodiments herein which provide various different switching devices having improved components including improved cylindrical gate contacts, improved source contacts, and/or improved drain contacts. These improved systems and components thereof may be implemented in vertical transistor structures which also include the aforementioned cylindrical pillar and cylindrical gate contact in comparison to conventional surface transistor structures.

Abstract: A method of forming a cylindrical vertical transistor; the method, according to one embodiment, includes: forming a cylindrical pillar from a single block of silicon, forming an oxide layer over an exterior of the cylindrical pillar and exposed surfaces of the block of silicon, coating the oxide layer with a spin-on-glass (SOG), depositing a source mask over a majority of the SOG coating, and removing a portion of the SOG coating and underlying oxide layer, where the portion removed is defined by the source mask. Other systems and methods are also described in additional embodiments herein which provide various different improved processes of forming the cylindrical gate contacts, the source contacts, and/or the drain contacts for vertical transistor structures which also include the aforementioned cylindrical pillar channel structures and cylindrical gate in comparison to conventional surface transistor structures.