Abstract: Integrating magnetic random access memory with logic is disclosed. The magnetic tunnel junction stack of a magnetic memory cell is disposed within a dielectric layer which serves as a via level of an interlevel dielectric layer with a metal level above the via level. An integration scheme for forming dual damascene structures for interconnects can be formed to logic and memory cells easily.

Abstract: Emerging memory chips and methods for forming an emerging memory chip are presented. For example, magnetic random access memory (MRAM) chip magnetic shielding at the device-level is disclosed. The MRAM chip includes a magnetic shield structure that is substantially surrounding a magnetic tunnel junction (MTJ) bit or device of a MTJ array. The magnetic shield may be configured in the form of a cylindrical shield structure or magnetic shield spacer that substantially surrounds the MTJ bit or device. The magnetic shield structure in the form of cylindrical shield structure or magnetic shield spacer may include top and/or bottom plate shield. The magnetic shield structure in various forms and configurations protect the MTJ stack from external or local magnetic fields. This magnetic shielding structure is applicable for both in-plane and perpendicular MRAM chips.

Abstract: Integrated circuits and methods of forming the same are provided herein. In an embodiment, an integrated circuit includes a semiconductor substrate that has an isolated well. A multilayer metallization stack overlies the semiconductor substrate. The multilayer metallization stack includes a metal layer, a functional via, and a dummy metal feature. The metal layer includes a first line in electrical communication with the isolated well through a contact. The functional via is in electrical communication with the first line and the contact. The dummy metal feature is in electrical communication with the functional via.

Abstract: Devices and methods for forming a device are disclosed. At least one die is provided. A redistribution layer having a fan-out region extends concentrically outwards from an outer perimeter of the at least one die. A seal ring is disposed in the fan-out region of the redistribution layer.

Abstract: Device and methods of forming a device are disclosed. The method includes providing a substrate and a first upper dielectric layer over first, second and third regions of the substrate. The first upper dielectric layer includes a first upper interconnect level with a plurality of metal lines in the first and second regions. A MRAM cell which includes a MTJ element sandwiched between top and bottom electrodes is formed in the second region. The bottom electrode is in direct contact with the metal line in the first upper interconnect level of the second region. A dielectric layer which includes a second upper interconnect level with a dual damascene interconnect in the first region and a damascene interconnect in the second region is provided over the first upper dielectric layer. The dual damascene interconnect in the first region is coupled to the metal line in the first region and the damascene interconnect in the second region is coupled to the MTJ element.

Abstract: Devices and methods of forming a device are disclosed. The method includes providing a substrate and a first upper dielectric layer over first and second regions of the substrate. The first upper dielectric layer includes a first upper interconnect level with a plurality of metal lines in the regions. A two-terminal device element which includes a device layer coupled in between first and second terminals is formed over the first upper dielectric layer in the second region. The first terminal contacts the metal line in the first upper interconnect level of the second region and the second terminal is formed on the device layer. An encapsulation liner covers at least exposed side surfaces of the device layer of the two-terminal device element. A dielectric layer which includes a second upper interconnect level with dual damascene interconnects is provided in the regions.

Abstract: Integrated circuits and methods for fabricating integrated circuits with magnetic tunnel junction (MTJ) structures are provided. An exemplary method for fabricating an integrated circuit includes forming an MTJ structure including a top electrode layer. The MTJ structure has a first sidewall and a second sidewall separated from the first sidewall by a first width. The method includes forming a conductive etch stop on the top electrode layer. The conductive etch stop has a second width greater than the first width. The method also includes depositing dielectric material over the conductive etch stop and the MTJ structure. The method further includes etching the dielectric material to form a trench exposing the conductive etch stop. Also, the method includes forming a conductive via in the trench over and in electrical communication with the conductive etch stop.

Abstract: Devices and methods for forming a device are disclosed. A substrate is provided. The substrate has first and second major surfaces. A capacitor is disposed in the substrate. The capacitor includes a first electrode, a second electrode and an insulator separating the first and second electrodes. The second electrode encloses the first electrode and the insulator.

Abstract: Device and methods of forming a device are disclosed. The method includes providing a substrate and a first upper dielectric layer over first, second and third regions of the substrate. The first upper dielectric layer includes a first upper interconnect level with a plurality of metal lines in the first and second regions. A MRAM cell which includes a MTJ element sandwiched between top and bottom electrodes is formed in the second region. The bottom electrode is in direct contact with the metal line in the first upper interconnect level of the second region. A dielectric layer which includes a second upper interconnect level with a dual damascene interconnect in the first region and a damascene interconnect in the second region is provided over the first upper dielectric layer. The dual damascene interconnect in the first region is coupled to the metal line in the first region and the damascene interconnect in the second region is coupled to the MTJ element.

Abstract: High density resistive memory structures, integrate circuits with high density resistive memory structures, and methods for fabricating high density resistive memory structures are provided. In an embodiment, a high density resistive memory structure includes a semiconductor substrate and a plurality of first electrodes in a first plane in and/or over the semiconductor substrate. Further, the high density resistive memory structure includes a plurality of second electrodes in a second plane in and/or over the semiconductor substrate. The second plane is parallel to the first plane, and each second electrode in the plurality of second electrodes crosses over or under each first electrode in the plurality of first electrodes at a series of cross points. Each second electrode in the plurality of second electrodes is non-linear and the series of cross points formed by each respective second electrode is non-linear.

Abstract: Methods of producing integrated circuits are provided. An exemplary method includes patterning a source line photoresist mask to overlie a source line area of a substrate while exposing a drain line area. The source line area is between a first and second memory cell and the drain line area is between the second and a third memory cell. A source line is formed in the source line area. A source line dielectric is concurrently formed overlying the source line while a drain line dielectric is formed overlying a drain line area. A drain line photoresist mask is patterned to overlie the source line in an active section while exposing the source line in a strap section, and while exposing the drain line area. The drain line dielectric is removed from over the drain line area while a thickness of the source line dielectric in the strap section is reduced.

Abstract: Methods of producing integrated circuits are provided. An exemplary method includes patterning a source line photoresist mask to overlie a source line area of a substrate while exposing a drain line area. The source line area is between a first and second memory cell and the drain line area is between the second and a third memory cell. A source line is formed in the source line area. A source line dielectric is concurrently formed overlying the source line while a drain line dielectric is formed overlying a drain line area. A drain line photoresist mask is patterned to overlie the source line in an active section while exposing the source line in a strap section, and while exposing the drain line area. The drain line dielectric is removed from over the drain line area while a thickness of the source line dielectric in the strap section is reduced.

Abstract: Integrated circuits and methods of forming the same are provided herein. In an embodiment, an integrated circuit includes a semiconductor substrate that has an isolated well. A multilayer metallization stack overlies the semiconductor substrate. The multilayer metallization stack includes a metal layer, a functional via, and a dummy metal feature. The metal layer includes a first line in electrical communication with the isolated well through a contact. The functional via is in electrical communication with the first line and the contact. The dummy metal feature is in electrical communication with the functional via.

Abstract: A method for fabricating an integrated circuit includes forming a first opening in an upper dielectric layer, the first opening having a first width, forming a second opening in a lower dielectric layer, the lower dielectric layer being below the upper dielectric layer, the second opening having a second width that is narrower than the first width, the second opening being substantially centered underneath the first opening so as to form a stepped via structure, conformally depositing an aluminum material layer in the stepped via structure and over the upper dielectric layer, and forming a passivation layer over the aluminum material layer.

Abstract: Methods of fabricating a dome-shaped MTJ TE and the resulting devices are provided. Embodiments include forming a MRAM stack having a laterally separated MTJ structures and the MRAM and a logic stack each having a SiN layer; forming first trenches through the MRAM stack to a portion of the SiN layer above an MTJ structure; forming second trenches through the SiN layer fully landing on an upper portion of the MTJ structures and removing the SiN layer of the logic stack; forming a TaN layer over the MRAM and logic stack; removing portions of the TaN layer on opposite sides of the MTJ structures and therebetween; forming an oxide layer over the MRAM and logic stacks; and forming vias through the oxide layer of the MRAM stack down the TaN layer above MTJ structures and a via through the logic stack.

Abstract: An integrated circuit includes a copper hillock-detecting structure. The copper hillock-detecting structure includes a copper metallization layer and an intermediate plate structure spaced apart from adjacent to the copper metallization layer. The intermediate plate structure includes a conducting material plate. The intermediate plate structure further includes a plurality of conductive vias that are electrically and physically connected with the conducting material plate. The copper hillock-detecting structure further includes a sensing plate adjacent to the intermediate plate and electrically and physically connected with the plurality of vias such that the vias are disposed between the intermediate plate and the sensing plate.

Abstract: Magnetic random access memory (MRAM) packages with magnetic shield protections and methods of forming thereof are presented. Package contact traces are formed on the first major surface of the package substrate and package balls are formed on the second major surface of the package substrate. A die having active and inactive surfaces is provided on the first major surface of the package substrate. The die includes a magnetic storage element, such as an array of magnetic tunnel junctions (MTJs), formed in the die, die microbumps formed on the active surface. The package includes a top magnetic shield layer formed on the inactive surface of the die. The package may also include a first bottom magnetic shield in the form of magnetic shield traces disposed below the package contact traces. The package may further include a second bottom magnetic shield in the form of magnetic permeable underfill dielectric material.

Abstract: Devices and methods for forming a device are disclosed. The method includes providing a substrate having first and second surfaces. At least one through silicon via (TSV) opening is formed in the substrate. The TSV opening extends through the first and second surfaces of the substrate. An alignment trench corresponding to an alignment mark is formed in the substrate. The alignment trench extends from the first surface of the substrate to a depth shallower than a depth of the TSV opening. A dielectric liner layer is provided over the substrate. The dielectric liner layer at least lines sidewalls of the TSV opening. A conductive layer is provided over the substrate. The conductive layer fills at least the TSV opening to form TSV contact. A redistribution layer (RDL) is formed over the substrate. The RDL layer is patterned using a reticle to form at least one opening which corresponds to a TSV contact pad. The reticle is aligned using the alignment mark in the substrate.

Abstract: Devices and methods of forming a device are disclosed. The method includes providing a substrate defined with at least first and second regions and providing a plurality of interlevel dielectric (ILD) levels having tight pitch over the first and second regions of the substrate. An ILD level of which a two-terminal element disposed thereon corresponds to a first ILD level and its metal level corresponds to Mx, an immediate ILD level overlying the metal level Mx corresponds to a second ILD level includes via level Vx and metal level Mx+1 and the next overlying ILD level corresponds to a third ILD level includes via level Vx+1 and metal level Mx+2. The method includes forming a two-terminal device element is formed in between metal level Mx and via level Vx+1 in the first region.

Abstract: Three-dimensional integrated circuit structures providing thermoelectric cooling and methods for cooling such integrated circuit structures are disclosed. In one exemplary embodiment, a three-dimensional integrated circuit structure includes a plurality of integrated circuit chips stacked one on top of another to form a three-dimensional chip stack, a thermoelectric cooling daisy chain comprising a plurality of vias electrically connected in series with one another formed surrounding the three-dimensional chip stack, a thermoelectric cooling plate electrically connected in series with the thermoelectric cooling daisy chain, and a heat sink physically connected with the thermoelectric cooling plate.