Abstract: Embodiments of the present invention include multiple independent terminals for a plurality of devices in a stack configuration within a semiconductor. In one embodiment, a semiconductor comprises: a first device at a first semiconductor level within a multi terminal device stack; wherein the first device is coupled to a first terminal; a second device at a second semiconductor level within the multi terminal device stack, wherein the second device is coupled to a second terminal; a third terminal is coupled to the second device and a fourth terminal is coupled to the first device, wherein the first terminal and second terminal are independently coupled to the first device and second device respectively. The first terminal, the second terminal, the third terminal and the fourth terminal couple components included in the multi terminal stack to components not included in the multi terminal stack.

Abstract: Embodiments of the present invention include multiple independent terminals for a plurality of devices in a stack configuration within a semiconductor. In one embodiment, a multi terminal fabrication process comprises: performing an initial pillar layer formation process to create layers of a multi terminal stack; forming a first device in the layers of the multi terminal stack; forming a second device in the layers of the multi terminal stack; and constructing a set of terminals comprising: a first terminal coupled to the first device, a second terminal coupled to the second device; and a third terminal coupled to the first device; wherein at least two terminals in the set of terminals are independent. The third terminal can be coupled to the second device.

Abstract: Embodiments of the present invention include multiple independent terminals for a plurality of devices in a stack configuration within a semiconductor. In one embodiment, a semiconductor comprises: a first device at a first semiconductor level within a multi terminal device stack; wherein the first device is coupled to a first terminal; a second device at a second semiconductor level within the multi terminal device stack, wherein the second device is coupled to a second terminal; and a third terminal is coupled to the first device, wherein the first terminal and second terminal are independently coupled to the first device and second device respectively. The third terminal can be coupled to the second device. The first terminal, the second terminal, and third terminal and couple components included in the multi terminal stack to components not included in the multi terminal stack.

Abstract: Embodiments of the present invention include multiple independent terminals for a plurality of devices in a stack configuration within a semiconductor. In one embodiment, a multi terminal fabrication process comprises: performing an initial pillar layer formation process to create layers of a multi terminal stack; forming a first device in the layers of the multi terminal stack; forming a second device in the layers of the multi terminal stack; and constructing a set of terminals comprising: a first terminal coupled to the first device, a second terminal coupled to the second device; and a third terminal coupled to the first device; wherein at least two terminals in the set of terminals are independent. The third terminal can be coupled to the second device.

Abstract: Embodiments of the present invention include multiple independent terminals for a plurality of devices in a stack configuration within a semiconductor. In one embodiment, a multi terminal fabrication process comprises: performing an initial pillar layer formation process to create layers of a multi terminal stack; forming a first device in the layers of the multi terminal stack; forming a second device in the layers of the multi terminal stack; and constructing a set of terminals comprising: a first terminal coupled to the first device, a second terminal coupled to the second device; and a third terminal coupled to the first device; wherein at least two terminals in the set of terminals are independent. The third terminal can be coupled to the second device.

Abstract: A method for manufacturing a magnetic memory element array that includes the use of a Ru hard mask layer and a diamond like carbon hard mask layer formed over the Ru hard mask layer. A plurality of magnetic memory element layers are deposited over a wafer and a Ru hard mask layer is deposited over the plurality of memory element layers. A layer of diamond like carbon is deposited over the Ru hard mask layer, and a photoresist mask is formed over the layer of diamond like carbon. A reactive ion etching is then performed to transfer the image of the photoresist mask onto the diamond like carbon mask, and an ion milling is performed to transfer the image of the patterned diamond like carbon mask onto the underlying Ru hard mask and memory element layers. The diamond like carbon mask can then be removed by reactive ion etching.

Abstract: A method for manufacturing a magnetic memory element array that includes the use of a Ru hard mask layer and a diamond like carbon hard mask layer formed over the Ru hard mask layer. A plurality of magnetic memory element layers are deposited over a wafer and a Ru hard mask layer is deposited over the plurality of memory element layers. A layer of diamond like carbon is deposited over the Ru hard mask layer, and a photoresist mask is formed over the layer of diamond like carbon. A reactive ion etching is then performed to transfer the image of the photoresist mask onto the diamond like carbon mask, and an ion milling is performed to transfer the image of the patterned diamond like carbon mask onto the underlying Ru hard mask and memory element layers. The diamond like carbon mask can then be removed by reactive ion etching.

Abstract: A method for manufacturing a magnetic random access memory array at a density greater than would be possible using photolithography. A template is formed having a pattern that is configured to define a memory array. A block copolymer material is deposited onto the template and annealed to form narrow cylinders of ordered block copolymer material. A metal oxide is then diffused into the cylinders to form narrow metal oxide cylinders. The metal oxide cylinders can then be used as mask structures to pattern a hard mask layer. An ion milling process can then be performed to transfer the image of the patterned hard mask onto an underlying magnetic memory material to form an array having features sizes smaller than what would be possible using photolithography.

Abstract: Embodiments of the present invention include multiple independent terminals for a plurality of devices in a stack configuration within a semiconductor. In one embodiment, a semiconductor comprises: a first device at a first semiconductor level within a multi terminal device stack; wherein the first device is coupled to a first terminal; a second device at a second semiconductor level within the multi terminal device stack, wherein the second device is coupled to a second terminal; and a third terminal is coupled to the first device, wherein the first terminal and second terminal are independently coupled to the first device and second device respectively. The third terminal can be coupled to the second device. The first terminal, the second terminal, and third terminal and couple components included in the multi terminal stack to components not included in the multi terminal stack.

Abstract: Embodiments of the present invention include multiple independent terminals for a plurality of devices in a stack configuration within a semiconductor. In one embodiment, a multi terminal fabrication process comprises: performing an initial pillar layer formation process to create layers of a multi terminal stack; forming a first device in the layers of the multi terminal stack; forming a second device in the layers of the multi terminal stack; and constructing a set of terminals comprising: a first terminal coupled to the first device, a second terminal coupled to the second device; and a third terminal coupled to the first device; wherein at least two terminals in the set of terminals are independent. The third terminal can be coupled to the second device.

Abstract: A method for manufacturing an array of small pitch small feature size structures on a wafer. The method includes depositing a device layer, depositing a hard mask layer over the device layer, depositing a thin SiO2 adhesion layer over the hard mask layer and then forming a photoresist mask over the SiO2 adhesion layer. The presence of the SiO2 adhesion layer prevents toppling or deformation of the photoresist mask, thereby allowing the image of the photoresist mask to be accurately and reliably transferred onto the underlying hard mask. Then, the image of the hard mask can be accurately transferred to the underlying device layer.

Abstract: A method for improving photo resist adhesion to an underlying hard mask layer. The method includes a cleaning step that includes applying tetramethylammonium hydroxide (TMAH) to coat a hard mask layer of a wafer. The method further includes puddle developing the wafer for a first desired amount of time, and rinsing the wafer in running water for a second desired amount of time. The method further includes spin drying the wafer, and baking the wafer for a third desired amount of time. The method concludes with the proceeding of subsequent photolithographic processes on the wafer.

Abstract: A method for manufacturing magnetic random access memory. The method allows very high density magnetic memory elements to be formed on a magnetic memory chip. A magnetic memory element material is deposited and a diamond like carbon (DLC) hard mask is formed over the magnetic memory element material. An ion or atom bombardment process such as ion milling is performed to remove portions of the magnetic memory element material that are not protected by the hard mask to form a plurality of magnetic memory element pillars. Because the diamond like carbon hard mask is resistant to the material removal processes such as ion milling, it can be made very thin (10-20 nm), which reduces shadowing while still allowing a process such as ion milling to be used to define the magnetic data element pillars. This advantageously allows the pillars to be formed with well defined, vertical sidewalls, and avoiding shorting.

Abstract: A method for improving photo resist adhesion to an underlying hard mask layer. The method includes a cleaning step that includes applying tetramethylammonium hydroxide (TMAH) to coat a hard mask layer of a wafer. The method further includes puddle developing the wafer for a first desired amount of time, and rinsing the wafer in running water for a second desired amount of time. The method further includes spin drying the wafer, and baking the wafer for a third desired amount of time. The method concludes with the proceeding of subsequent photolithographic processes on the wafer.

Abstract: A method for manufacturing a magnetic random access memory array at a density greater than would be possible using photolithography. A template is formed having a pattern that is configured to define a memory array. A block copolymer material is deposited onto the template and annealed to form narrow cylinders of ordered block copolymer material. A metal oxide is then diffused into the cylinders to form narrow metal oxide cylinders. The metal oxide cylinders can then be used as mask structures to pattern a hard mask layer. An ion milling process can then be performed to transfer the image of the patterned hard mask onto an underlying magnetic memory material to form an array having features sizes smaller than what would be possible using photolithography.

Abstract: A method for manufacturing magnetic random access memory. The method allows very high density magnetic memory elements to be formed on a magnetic memory chip. A magnetic memory element material is deposited and a diamond like carbon (DLC) hard mask is formed over the magnetic memory element material. An ion or atom bombardment process such as ion milling is performed to remove portions of the magnetic memory element material that are not protected by the hard mask to form a plurality of magnetic memory element pillars. Because the diamond like carbon hard mask is resistant to the material removal processes such as ion milling, it can be made very thin (10-20 nm), which reduces shadowing while still allowing a process such as ion milling to be used to define the magnetic data element pillars. This advantageously allows the pillars to be formed with well defined, vertical sidewalls, and avoiding shorting.

Abstract: A method for manufacturing a magnetic random access memory array at a density greater than would be possible using photolithography. A hard mask material is deposited over a magnetic memory element material, and a chemical template layer such as brush or mat material is deposited over the hard mask. A mask structure is formed over the soluble polymer. The mask structure is configured with openings having a center to center spacing that is an integer multiple of a block copolymer material. The openings in the mask structure can be shrunk by depositing a spacer material. The chemical template layer is chemically patterned, such as by a quick plasma exposure and the mask is removed. A block copolymer material is then deposited over the chemical template and annealed to form block copolymer cylinders that are located over the patterned portions of the chemical template and between the patterned portions.

Abstract: A method for manufacturing a magnetic random access memory array at a density greater than would be possible using photolithography. The method involves patterning a chemical template material with patterned portions separated by a center to center distance that is substantially equal to a natural period of a block copolymer. A block copolymer material is then deposited and annealed to form self assembled cylinders that are located over the patterned regions of the chemical template and also over areas between the patterned regions. The chemical template layer can be patterned by depositing a first, preliminary block copolymer, over a mask structure and annealing the mask structure to form cylinders in the openings in the mask structure. The cylinders can be removed leaving openings, and a UV exposure can be performed to expose and treat portions of the chemical template layer that are exposed through the opening.

Abstract: Block copolymer lithography has emerged as an alternative lithographic method to achieve large-area, high-density patterns at resolutions near or beyond the limit of conventional lithographic techniques for the formation of bit patterned media and discrete track media. In one embodiment, a structure includes a plurality of nanostructures extending upwardly from a substrate and a porous membrane extending across upper ends of the plurality of nanostructures. Other systems and methods are disclosed as well.

Abstract: Patterned media and associated methods of fabrication are provided in which vertical magnetic grains are grown on a patterned seed layer. The patterned seed layer includes a matrix of islands of a first seed material. Each island of first seed material is separated from other islands by a region of second seed material. The first seed material is selected to initiate growth of magnetic material, and the second seed material is selected to initiate growth of non-magnetic material. Subsequently, magnetic material is grown on the first seed material and non-magnetic material is grown on the second seed material. Deposition may be simultaneously. The magnetic and non-magnetic materials form well-defined vertical columns over the first and second seed materials respectively. Thus, each island behaves as an isolated magnetic unit, which switches independently from its neighbor units, which are magnetically separated by the non-magnetic material.