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 structure using a Ru hard mask and a post pillar thermal annealing process. A Ru hard mask is formed over a plurality of memory element layers and an ion milling is performed to transfer the image of the Ru hard mask onto the underlying memory element layers. A high-angle ion milling an be performed to remove any redeposited material from the sides of the memory element layers, and a non-magnetic, dielectric material can be deposited. A thermal annealing process can then be performed to repair any damage caused by the previously performed ion milling processes.

Abstract: Embodiments of the present invention facilitate efficient and effective increased memory cell density configuration. In one embodiment, a semiconductor device comprises: a first pillar magnetic tunnel junction (pMTJ) memory cell that comprises a first pMTJ located in a first level in the semiconductor device; and a second pillar magnetic tunnel junction (pMTJ) memory cell that comprises a second pMTJ located in a second level in the semiconductor device, wherein the second pMTJ location with respect to the first pMTJ is coordinated to comply with a reference pitch for the memory cell. A reference pitch is associated a first switch coupled to the first pMTJ and the second pitch reference component is a second switch coupled to the second pMTJ. The first switch and second switch can be transistors. The reference pitch coordination facilitates reduced pitch between memory cells and increased information storage capacity of bits per memory device area.

Abstract: Embodiments of the present invention facilitate efficient and effective increased memory cell density configuration. In one embodiment, the method comprises: forming a first pitch reference component and a second pitch reference component; forming a first pillar magnetic tunnel junction (pMTJ) located in a first level and a second pMTJ located in a second level, wherein the location of the second pMTJ with respect to the first pMTJ is coordinated based upon a reference pitch distance between the first pitch reference component and first pitch reference component. In one exemplary implementation, the first pitch reference component is a first switch coupled to the first pMTJ and the second pitch reference component is a second switch coupled to the second pMTJ. The reference component size can be based upon a minimum lithographic processing dimension.

Abstract: A method for manufacturing a magnetic memory element structure using a Ru hard mask and a post pillar thermal annealing process. A Ru hard mask is formed over a plurality of memory element layers and an ion milling is performed to transfer the image of the Ru hard mask onto the underlying memory element layers. A high-angle ion milling an be performed to remove any redeposited material from the sides of the memory element layers, and a non-magnetic, dielectric material can be deposited. A thermal annealing process can then be performed to repair any damage caused by the previously performed ion milling processes.

Abstract: A method for manufacturing a magnetic memory element structure using a Ru hard mask and a self-aligned pillar formation process. A plurality of magnetic memory element layers are deposited over a substrate, including a magnetic reference layer, a non-magnetic barrier layer deposited over the magnetic reference layer, a magnetic free layer deposited over the non-magnetic barrier layer and a Ru hard mask layer deposited over the Ru hard mask layer. A mask structure is formed over the Ru hard mask and the image of the mask structure is transferred to the Ru hard mask. A first ion milling is performed to transfer the image of the patterned Ru hard mask onto the underlying magnetic free layer and non-magnetic barrier layer, the first ion milling being terminated when the magnetic reference layer has been reached. A non-magnetic dielectric protective layer is then deposited and a second ion milling is performed.

Abstract: A method for a photo and/or electron beam lithographic fabricating processes for producing a pillar array test device. The method includes receiving a wafer having a plurality of bit cells arranged in a grid and etching a plurality of bottom electrode traces to connect a plurality of bottom electrode pads in a centrally located bit cell to each of the bit cells in the grid. The method further includes fabricating an array of magnetic tunnel junction pillars onto each respective pad in the centrally located bit cell. The wafer is then planarized. The method further includes etching a plurality of top electrode traces to connect the plurality of magnetic tunnel junction pillars to each of the bit cells in the grid, and outputting the wafer for subsequent testing.

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: A method for testing individual memory elements or sets of memory elements of an array of magnetic memory elements. The method involves forming a mask such as photoresist mask over an array memory elements. The mask is configured with an opening over each of the selected memory elements to be tested. The mask can be formed of photoresist which can be patterned by focused electron beam exposure to form opening at features sizes smaller than those available using standard photolithographic processes. An electrically conductive material is deposited over the mask and into the openings in the mask to make electrical contact with the selected memory element or memory elements to be tested. Then, electrical connection can be made with the electrically conductive material to test the selected one or more magnetic memory elements.

Abstract: A method for a photo and/or electron beam lithographic fabricating processes for producing a pillar array test device. The method includes receiving a wafer having a plurality of bit cells arranged in a grid and etching a plurality of bottom electrode traces to connect a plurality of bottom electrode pads in a centrally located bit cell to each of the bit cells in the grid. The method further includes fabricating an array of magnetic tunnel junction pillars onto each respective pad in the centrally located bit cell. The wafer is then planarized. The method further includes etching a plurality of top electrode traces to connect the plurality of magnetic tunnel junction pillars to each of the bit cells in the grid, and outputting the wafer for subsequent testing.

Abstract: A Magnetic Tunnel Junction (MTJ) device including pillar contacts coupling the free magnetic layer of cell pillars to a top contact. The pillar contacts are electrically isolated from one or more other portions of the cell pillar by one or more self-aligned sidewall insulators. The MTJ device further including one of a static magnetic compensation layer or an exchange spring layer in the cell pillar.

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 a photo and/or electron beam lithographic fabricating processes for producing a pillar array test device. The method includes receiving a wafer having a plurality of bit cells arranged in a grid and etching a plurality of bottom electrode traces to connect a plurality of bottom electrode pads in a centrally located bit cell to each of the bit cells in the grid. The method further includes fabricating an array of magnetic tunnel junction pillars onto each respective pad in the centrally located bit cell. The wafer is then planarized. The method further includes etching a plurality of top electrode traces to connect the plurality of magnetic tunnel junction pillars to each of the bit cells in the grid, and outputting the wafer for subsequent testing.

Abstract: A method of manufacturing a Magnetic Tunnel Junction (MTJ) device including pillar contacts coupling the free magnetic layer of MTJ pillars to a top contact. The pillar contacts are electrically isolated from one or more other portions of the MTJ pillar by one or more self-aligned sidewall insulators. The MTJ device further including one of a static magnetic compensation layer or an exchange spring layer in the MTJ pillar.

Abstract: Embodiments of the present invention facilitate efficient and effective increased memory cell density configuration. In one embodiment, the method comprises: forming a first pitch reference component and a second pitch reference component; forming a first pillar magnetic tunnel junction (pMTJ) located in a first level and a second pMTJ located in a second level, wherein the location of the second pMTJ with respect to the first pMTJ is coordinated based upon a reference pitch distance between the first pitch reference component and first pitch reference component. In one exemplary implementation, the first pitch reference component is a first switch coupled to the first pMTJ and the second pitch reference component is a second switch coupled to the second pMTJ. The reference component size can be based upon a minimum lithographic processing dimension.

Abstract: A method for testing individual memory elements or sets of memory elements of an array of magnetic memory elements. The method involves forming a mask such as photoresist mask over an array memory elements. The mask is configured with an opening over each of the selected memory elements to be tested. The mask can be formed of photoresist which can be patterned by focused electron beam exposure to form opening at features sizes smaller than those available using standard photolithographic processes. An electrically conductive material is deposited over the mask and into the openings in the mask to make electrical contact with the selected memory element or memory elements to be tested. Then, electrical connection can be made with the electrically conductive material to test the selected one or more magnetic memory elements.