Patent application number | Description | Published |
20080254576 | Method of fabricating a self-aligning damascene memory structure - A method of forming a three-dimensional, non-volatile memory array utilizing damascene fabrication techniques is disclosed. A bottom set of conductors is formed and a set of first pillar shaped elements of heavily doped semiconductor material as formed thereon. A mold is formed of insulating material having pillar shaped openings self-aligned with the first pillar shaped elements and a second semiconductor is deposited over the mold to form second pillar shaped elements aligned with the first pillar shaped elements. The pillar elements formed may be further processed by forming another mold of insulating material having trench openings aligned with the pillar shaped elements and then filling the trenches with conductive material to form conductors coupled to the pillar shaped elements. | 10-16-2008 |
20090004844 | Forming Complimentary Metal Features Using Conformal Insulator Layer - A method is provided to form densely spaced metal lines. A first set of metal lines is formed by etching a first metal layer. A thin dielectric layer is conformally deposited on the first metal lines. A second metal is deposited on the thin dielectric layer, filling gaps between the first metal lines. The second metal layer is planarized to form second metal lines interposed between the first metal lines, coexposing the thin dielectric layer and the second metal layer at a substantially planar surface. In some embodiments, planarization continues to remove the thin dielectric covering tops of the first metal lines, coexposing the first metal lines and the second metal lines, separated by the thin dielectric layer, at a substantially planar surface. | 01-01-2009 |
20090309089 | Non-Volatile Memory Arrays Comprising Rail Stacks with a Shared Diode Component Portion for Diodes of Electrically Isolated Pillars - 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. | 12-17-2009 |
20100044756 | METHOD OF FABRICATING A SELF-ALIGNING DAMASCENE MEMORY STRUCTURE - A method of forming a memory cell is provided, the method including forming a first pillar-shaped element comprising a first semiconductor material, forming a first mold comprising an opening self-aligned with the first pillar-shaped element, and depositing a second semiconductor material in the opening to form a second pillar-shaped element above the first pillar-shaped element. Other aspects are also provided. | 02-25-2010 |
20120187361 | Non-Volatile Memory Arrays Comprising Rail Stacks With A Shared Diode Component Portion For Diodes Of Electrically Isolated Pillars - 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. | 07-26-2012 |
20130175675 | METHOD OF FABRICATING A SELF-ALIGNING DAMASCENE MEMORY STRUCTURE - A method of forming a memory cell is provided. The method includes forming a first pillar-shaped element that includes a first semiconductor material, forming a first opening self-aligned with the first pillar-shaped element, and depositing a second semiconductor material in the first opening to form a second pillar-shaped element above the first pillar-shaped element. Other aspects are also provided. | 07-11-2013 |
20140117514 | METHOD OF FABRICATING A SELF-ALIGNING DAMASCENE MEMORY STRUCTURE - A method of forming a memory cell is provided. The method includes forming a first pillar-shaped element that includes a first semiconductor material, forming a first opening self-aligned with the first pillar-shaped element, and depositing a second semiconductor material in the first opening to form a second pillar-shaped element above the first pillar-shaped element. Other aspects are also provided. | 05-01-2014 |
20140272576 | METHODS AND APPARATUS FOR HIGH CAPACITY ANODES FOR LITHIUM BATTERIES - An electrode is provided for an electrochemical lithium battery cell. The electrode includes a bulk material that has a plurality of voids dispersed substantially throughout the bulk material. The bulk material is silicon. Numerous other aspects are provided. | 09-18-2014 |
20140272577 | METHODS AND APPARATUS FOR HIGH CAPACITY ANODES FOR LITHIUM BATTERIES - An electrode is provided for an electrochemical lithium battery cell. The electrode includes multiple silicon sheets, each silicon sheet including multiple apertures, each aperture extending all or partly through a thickness of the silicon sheet. Numerous other aspects are provided. | 09-18-2014 |