Abstract: The present invention relates to a process for refinery wastewater treatment. More particularly, the present invention relates to an automated process for treatment of refinery wastewater. The process of the present invention provides complete automation for controlling different critical parameters that enhance biological activity of activated sludge process (ASP) and helps in significant reduction in sludge recycling that increases the treatment efficiency.

Abstract: Imaging methods, imaging devices, transfer assemblies, and transfer member lubrication assemblies are described according to some aspects. According to one aspect, an imaging method includes forming a latent image using a first imaging member, using a marking agent, developing the latent image providing a developed image, after the developing, first transferring the marking agent of the developed image to an imaging transfer member, after the first transferring, second transferring the marking agent of the developed image from the imaging transfer member, and lubricating the imaging transfer member during the first and the second transferrings.

Abstract: A thermally written magnetic memory device is disclosed. The thermally written magnetic memory device includes a plurality of thermally written magnetic tunnel junction devices. Each thermally written magnetic tunnel junction device includes a super-paramagnetically stable data layer. The data layer includes a high coercivity at a read temperature such that a bit of data previously written to the data layer at a higher write temperature can be read from the data layer at the read temperature. The data layer has a low coercivity at the higher write temperature and data is written to the data layer at the higher write temperature. Therefore, at the lower read temperature, the thermally written magnetic memory device is a read only non-volatile memory and the data stored therein can be read many times but new data cannot be written to the data layer at the read temperature.

Abstract: Embodiments of the present invention provide a magnetic memory. In one embodiment, the magnetic memory comprises a magnetic memory cell and a conductor configured to provide a magnetic field to write the magnetic memory cell. Structure is configured to direct the magnetic field and reduce coercivity of the magnetic memory cell.

Abstract: A magnetic memory cell includes a first magneto-resistive device and a second magneto-resistive device. The first magneto-resistive device has a first sense layer. The second magneto-resistive device is connected in series with the first magneto-resistive device. The second magneto-resistive device has a second sense layer. At least one controlled nucleation site is placed on at least one of the first sense layer and the second sense layer.

Abstract: A thin film device and a method of providing thermal assistance therein is disclosed. Accordingly, a heater material is utilized to thermally assist in the operation of the thin film device. By utilizing a heater material to thermally assist in the operation of the thin film device, a substantial improvement in the accuracy and performance of the thin film device is achieved. A first aspect of the present invention is a thin film device. The thin film device includes at least one patterned thin film layer, a heater material coupled to the at least one patterned thin film layer for providing thermal assistance to the at least one of the patterned thin film layers and a conductor coupled to the heater material for supplying energy to the heater material.

Abstract: This invention provides a controlled temperature, thermal-assisted magnetic memory device. In a particular embodiment, there is an array of SVM cells, each characterized by an alterable orientation of magnetization and including a material wherein the coercivity is decreased upon an increase in temperature. In addition, at least one reference SVM (RSVM) cell substantially similar to and in close proximity to the SVM cells of the array is provided. A provided feedback control temperature controller receives a feedback voltage from the reference SVM cell, corresponding to temperature, and adjusts power applied to the RSVM cell and SVM cell. An associated method of use is further provided.

Abstract: A thin film device and a method of providing thermal assistance therein is disclosed. Accordingly, a heater material is utilized to thermally assist in the operation of the thin film device. By utilizing a heater material to thermally assist in the operation of the thin film device, a substantial improvement in the accuracy and performance of the thin film device is achieved. A first aspect of the present invention is a thin film device. The thin film device includes at least one patterned thin film layer, a heater material coupled to the at least one patterned thin film layer for providing thermal assistance to the at least one of the patterned thin film layers and a conductor coupled to the heater material for supplying energy to the heater material.

Abstract: A magnetic memory cell write current threshold detector. The magnetic memory cell write current threshold detector includes a first MRAM test cell receiving a write current and sensing when the write current exceeds a first threshold, and a second MRAM test cell receiving the write current and sensing when the write current exceeds a second threshold.

Abstract: A magnetic memory cell includes first and second magneto-resistive devices connected in series. The first and second magneto-resistive devices have sense layers with different coercivities. Magnetic Random Access Memory (MRAM) devices may include arrays of these memory cells.

Abstract: An electro-magnetic device, such as magnetic memory device, is disclosed that includes means for structuring, attenuating or eliminating stray fields at the boundaries that produce an offset in the magneto-resistive response. The device comprises a conductive first layer and the attenuating means comprises a sink layer, electro-magnetically coupled to the first layer, to attenuate the stray boundary magneto-resistive offset at a boundary of the first layer during electrical operation.

Abstract: A magnetic memory cell includes first and second magneto-resistive devices connected in series. The first and second magneto-resistive devices have sense layers with different coercivities. Magnetic Random Access Memory (MRAM) devices may include arrays of these memory cells.

Abstract: A ferromagnetic data layer of a magnetic memory element is formed with a controlled nucleation site. In some embodiments, the nucleation site may be a divot in the data layer or a protrusion from the data layer. A Magnetic Random Access Memory (“MRAM”) device may include an array of magnetic memory elements having data layers with controlled nucleation sites.

Abstract: In one embodiment, a memory device includes a plurality of magnetic data cells and a magnetic reference cell extending uninterrupted along more than one of the plurality of data cells.

Abstract: A thin film device and a method of providing thermal assistance therein is disclosed. Accordingly, a heater material is utilized to thermally assist in the operation of the thin film device. By utilizing a heater material to thermally assist in the operation of the thin film device, a substantial improvement in the accuracy and performance of the thin film device is achieved. A first aspect of the present invention is a thin film device. The thin film device includes at least one patterned thin film layer, a heater material coupled to the at least one patterned thin film layer for providing thermal assistance to the at least one of the patterned thin film layers and a conductor coupled to the heater material for supplying energy to the heater material.

Abstract: A magneto-resistive element is constructed. A ferromagnetic sense layer is deposited on a surface. The ferromagnetic sense layer is patterned. An etch is performed in preparation for depositing a dielectric layer. The dielectric layer is deposited over the sense layer. A ferromagnetic pinned layer is deposited over the dielectric layer.

Abstract: A magnetic memory array comprises a plurality of magnetic memory cells, a magnetic shielding disposed adjacent to at least one of the magnetic memory cells to reduce magnetic interference with respect to another of the magnetic memory cells, and an insulator disposed as to separate at least a portion of the magnetic shielding from the at least one magnetic memory cell. The magnetic shielding may be a magnetic shield layer, patterned magnetic shield materials, and/or magnetic particles embedded in the insulator.

Abstract: A magnetic memory cell includes first and second magneto-resistive devices connected in series. The first and second magneto-resistive devices have sense layers with different coercivities. Magnetic Random Access Memory (MRAM) devices may include arrays of these memory cells.

Abstract: A magnetic memory array comprises a plurality of magnetic memory cells, a magnetic shielding disposed adjacent to at least one of the magnetic memory cells to reduce magnetic interference with respect to another of the magnetic memory cells, and an insulator disposed as to separate at least a portion of the magnetic shielding from the at least one magnetic memory cell. The magnetic shielding may be a magnetic shield layer, patterned magnetic shield materials, and/or magnetic particles embedded in the insulator.

Abstract: A ferromagnetic data layer of a magnetic memory element is formed with a controlled nucleation site. The controlled nucleation sites improve the switching distribution of the magnetic memory elements, which increases reliability of writing to the magnetic memory elements. A Magnetic Random Access Memory (MRAM) device may include an array of such magnetic memory elements.