Abstract: A spin transfer torque magnetic random access memory (STT-MRAM) device includes magnetic tunnel junctions (MTJs) with reduced switching current asymmetry. At least one switching asymmetry balance layer (SABL) near the free layer of the MTJ reduces a first switching current Ic(p-ap) causing the value of the first switching current to be nearly equal to the value of a second switching current Ic(ap-p) without increasing the average switching current of the device. The SABL may be a non-magnetic switching asymmetry balance layer (NM-SABL) and/or a magnetic switching asymmetry balance layer (M-SABL).

Abstract: A magnetic tunnel junction (MTJ) storage element may comprise a pinned layer stack and a first functional layer. The pinned layer stack is formed of a plurality of layers comprising a bottom pinned layer, a coupling layer, and a top pinned layer. The first functional layer is disposed in the bottom pinned layer or the top pinned layer.

Abstract: Methods and apparatus for shielding a shielding a non-volatile memory, such as shielding a magnetic tunnel junction (MTJ) device from a magnetic flux are provided. In an example, a shielding layer is formed adjacent to an electrode of an MTJ device, such that the shielding layer substantially surrounds a surface of the electrode, and a metal line is coupled to the shielding layer. The metal line can be coupled to the shielding layer by a via.

Abstract: A magnetic tunnel junction (MTJ) storage element and method of forming the MTJ are disclosed. The magnetic tunnel junction (MTJ) storage element includes a pinned layer, a barrier layer, a free layer and a composite hardmask or top electrode. The composite hardmask/top electrode architecture is configured to provide a non-uniform current path through the MTJ storage element and is formed from electrodes having different resistance characteristics coupled in parallel. An optional tuning layer interposed between the free layer and the top electrode helps to reduce the damping constant of the free layer.

Abstract: A method of estimating damage to a magnetic tunnel junction (MTJ) element that includes providing an MTJ element having a magnetic barrier layer, the magnetic barrier layer having a periphery, a cross-sectional area and a thickness and comprising an inner region of undamaged magnetic barrier material and an outer region of damaged magnetic barrier material between the inner region and the periphery, determining a first value indicative of an electrical characteristic of the MTJ element, determining a second value indicative of the electrical characteristic that the MTJ element would have had if the outer region of damaged magnetic barrier material were not present and if the inner region of undamaged magnetic barrier material extended to the periphery, and calculating a value indicative of the size of the outer region of damaged magnetic barrier material from the first value and the second value. Also a computer configured to perform the method.

Abstract: Perpendicular magnetic anisotropy (PMA) type magnetic random access memory cells are constructed with a composite PMA layer to provide a magnetic tunnel junction (MTJ) with an acceptable thermal barrier, A PMA coupling layer is deposited between a first PMA layer and a second PMA layer to form the composite PMA layer. The composite PMA layer may be incorporated in PMA type MRAM cells or in-plane type MRAM cells.

Abstract: Partial perpendicular magnetic anisotropy (PPMA) type magnetic random access memory cells are constructed using processes and structural configurations that induce a directed static strain/stress on an MTJ to increase the perpendicular magnetic anisotropy. Consequently, reduced switching current of the MTJ results. The directed static strain/stress on the MTJ is induced in a controlled direction and/or with a controlled magnitude during fabrication. The MTJ is permanently subject to a predetermined directed stress and permanently includes the directed static strain/strain that provides reduced switching current.

Abstract: A spin transfer torque magnetic random access memory (STT-MRAM) device includes magnetic tunnel junctions (MTJs) with reduced switching current asymmetry. At least one switching asymmetry balance layer (SABL) near the free layer of the MTJ reduces a first switching current Ic(p-ap) causing the value of the first switching current to be nearly equal to the value of a second switching current Ic(ap-p) without increasing the average switching current of the device. The SABL may be a non-magnetic switching asymmetry balance layer (NM-SABL) and/or a magnetic switching asymmetry balance layer (M-SABL).

Abstract: A system and method for forming a magnetic tunnel junction (MTJ) storage element utilizes a composite free layer structure. The MTJ element includes a stack comprising a pinned layer, a barrier layer, and a composite free layer. The composite free layer includes a first free layer, a superparamagnetic layer and a nonmagnetic spacer layer interspersed between the first free layer and the superparamagnetic layer. A thickness of the spacer layer controls a manner of magnetic coupling between the first free layer and the superparamagnetic layer.

Abstract: Methods and apparatus for shielding a shielding a non-volatile memory, such as shielding a magnetic tunnel junction (MTJ) device from a magnetic flux are provided. In an example, a shielding layer is formed adjacent to an electrode of an MTJ device, such that the shielding layer substantially surrounds a surface of the electrode, and a metal line is coupled to the shielding layer. The metal line can be coupled to the shielding layer by a via.

Abstract: A separative extended gate field effect transistor based uric acid sensing device is provided, including: a substrate; a conductive layer including a silver paste layer on the substrate and a graphite-based paste layer on the silver paste layer; a conductive wire extended from the conductive layer; a titanium dioxide layer on the conductive layer; and a uric acid enzyme sensing film on the titanium dioxide layer.

Abstract: The invention provides a multi-electrode measuring system including a front end device which is a sensing device including a multi-electrode sensing device having a plurality of electrodes; a multi-channel fixture coupled to the multi-electrode sensing device; and a reference electrode. A back-end device as a virtual instrumentation is an electronic device including a read out circuit device coupled to the multi-channel fixture and the reference electrode for receiving each original signal from each electrode of the multi-electrode sensing device and the reference electrode determining a sample solution; a data acquisition device coupled to the read out circuit device for digitizing each original signal to form a digital signal and for array sampling; and a signal processing device coupled to the data acquisition device for processing each signal.

Abstract: A magnetic tunnel junction (MTJ) storage element may comprise a pinned layer stack and a first functional layer. The pinned layer stack is formed of a plurality of layers comprising a bottom pinned layer, a coupling layer, and a top pinned layer. The first functional layer is disposed in the bottom pinned layer or the top pinned layer.

Abstract: Methods for forming a magnetic tunnel junction (MTJ) storage element and MTJ storage elements formed are disclosed. The MTJ storage element includes a MTJ stack having a pinned layer stack, a barrier layer and a free layer. An adjusting layer is formed on the free layer, such that the free layer is protected from process related damages. A top electrode is formed on the adjusting layer and the adjusting layer and the free layer are etched utilizing the top electrode as a mask. A spacer layer is then formed, encapsulating the top electrode, the adjusting layer and the free layer. The spacer layer and the remaining portions of the MTJ stack are etched. A protective covering layer is deposited over the spacer layer and the MTJ stack.

Abstract: A magnetic memory element includes a pinned layer, a tunneling barrier layer, a free layer and a stabilizing layer. The tunneling barrier layer is disposed on the pinned layer. The free layer is disposed on the tunneling barrier layer. The stabilizing layer is disposed on the free layer.

Abstract: A magnetic tunnel junction (MTJ) with direct contact is manufactured having lower resistances, improved yield, and simpler fabrication. The lower resistances improve both read and write processes in the MTJ. The MTJ layers are deposited on a bottom electrode aligned with the bottom metal. An etch stop layer may be deposited adjacent to the bottom metal to prevent overetch of an insulator surrounding the bottom metal. The bottom electrode is planarized before deposition of the MTJ layers to provide a substantially flat surface. Additionally, an underlayer may be deposited on the bottom electrode before the MTJ layers to promote desired characteristics of the MTJ.

Abstract: A magnetic tunnel junction (MTJ) storage element and method of forming the MTJ are disclosed. The magnetic tunnel junction (MTJ) storage element includes a pinned layer, a barrier layer, a free layer and a composite hardmask or top electrode. The composite hardmask/top electrode architecture is configured to provide a non-uniform current path through the MTJ storage element and is formed from electrodes having different resistance characteristics coupled in parallel. An optional tuning layer interposed between the free layer and the top electrode helps to reduce the damping constant of the free layer.

Abstract: A system and method for forming a magnetic tunnel junction (MTJ) storage element utilizes a composite free layer structure. The MTJ element includes a stack comprising a pinned layer, a barrier layer, and a composite free layer. The composite free layer includes a first free layer, a superparamagnetic layer and a nonmagnetic spacer layer interspersed between the first free layer and the superparamagnetic layer. A thickness of the spacer layer controls a manner of magnetic coupling between the first free layer and the superparamagnetic layer.

Abstract: The invention provides a multi-electrode measuring system including a front end device which is a sensing device including a multi-electrode sensing device having a plurality of electrodes; a multi-channel fixture coupled to the multi-electrode sensing device; and a reference electrode. A back-end device as a virtual instrumentation is an electronic device including a read out circuit device coupled to the multi-channel fixture and the reference electrode for receiving each original signal from each electrode of the multi-electrode sensing device and the reference electrode determining a sample solution; a data acquisition device coupled to the read out circuit device for digitizing each original signal to form a digital signal and for array sampling; and a signal processing device coupled to the data acquisition device for processing each signal.