Abstract: The present disclosure relates to systems and methods for tunable electrodynamic wireless power receivers. In some examples, a wireless power receiver electromechanically converts energy from a magnetic field using an oscillating or continuously rotating magnet. A sensing device detects an operational parameter of the receiver, and a tuning device initiates a tuning action based on the operational parameter.

Abstract: Various embodiments relate to a hybrid electromechanical transformer system and related methods. One such system comprises an electromechanical transformer device comprising an oscillating suspension element, wherein the oscillating suspension element comprises a platform and one or more suspension arms. The one or more suspension arms are attached to a respective side of the platform, wherein the oscillating suspension element further comprises a frame. The device further comprises at least one piezoelectric element attached to the one or more suspension arms of the oscillating suspension element of the oscillating suspension element: a piezoelectric transducer port coupled to the at least one piezoelectric element: a permanent magnet attached to the platform of the oscillating suspension element; a coil electrodynamically coupled with the permanent magnet and attached to the frame of the oscillating suspension element; and an electrodynamic transducer port coupled to the coil.

Abstract: Embodiments of the present disclosure provide systems and methods for wirelessly charging household batteries without having to remove the batteries from battery-powered user-devices, consumer electronics, or other applications to which the batteries are being deployed. In one embodiment, a wireless rechargeable battery system comprises an electrical energy storage element for a wireless rechargeable battery; a wireless receiver for the wireless rechargeable battery, wherein the wireless receiver is configured to supply electrical energy to the electrical energy storage element in a presence of a magnetic field from a charging base station; and an internal electronics circuitry for the wireless rechargeable battery, wherein the internal electronics circuitry couples the electrical energy storage element and the wireless receiver.

Abstract: Embodiments of the present disclosure integrate magnetoelectric nanowire arrays within antenna assemblies to form ultra-compact antennas. An exemplary method comprises using a dielectrophoretic force to orient a magnetoelectric nanowire across an electrode gap separating a pair of electrodes; and transmitting or receiving electromagnetic waves through a magnetoelectric effect of the magnetoelectric nanowire. Other methods, apparatuses, and systems are also presented.

Abstract: Embodiments of the present disclosure integrate magnetoelectric nanowire arrays within antenna assemblies to form ultra-compact antennas. An exemplary nanowire antenna array device comprises a first electrode positioned across a second electrode, wherein an electrode gap separates the first electrode and the second electrode; and a magnetoelectric nanowire connected to the first electrode and the second electrode across the electrode gap without substrate clamping, wherein the nanowire antenna array device receives or transmits electromagnetic waves through the magnetoelectric effect.

Abstract: Various embodiments to mitigate the contamination of electroplated cobalt-platinum films on substrates are described. In one embodiment, a method of manufacture of a device includes depositing a diffusion barrier over a substrate, depositing a seed layer upon the diffusion barrier, and depositing a cobalt-platinum magnetic layer upon the seed layer. In a second embodiment, a method of manufacture of a device may include depositing a diffusion barrier over a substrate and depositing a cobalt-platinum magnetic layer upon the diffusion barrier. In a third embodiment, a method of manufacture of a device may include depositing an adhesion layer over a substrate, depositing a seed layer upon the adhesion layer, and depositing a cobalt-platinum magnetic layer over the seed layer. Based in part on these methods of manufacture, improvements in the interfaces between the layers can be achieved after annealing with substantial improvements in the magnetic properties of the cobalt-platinum magnetic layer.

Abstract: The present disclosure relates to systems and methods for tunable electrodynamic wireless power receivers. In some examples, a wireless power receiver electromechanically converts energy from a magnetic field using an oscillating or continuously rotating magnet. A sensing device detects an operational parameter of the receiver, and a tuning device initiates a tuning action based on the operational parameter.

Abstract: Various embodiments to mitigate the contamination of electroplated cobalt-platinum films on substrates are described. In one embodiment, a method of manufacture of a device includes depositing a diffusion barrier over a substrate, depositing a seed layer upon the diffusion barrier, and depositing a cobalt-platinum magnetic layer upon the seed layer. In a second embodiment, a method of manufacture of a device may include depositing a diffusion barrier over a substrate and depositing a cobalt-platinum magnetic layer upon the diffusion barrier. In a third embodiment, a method of manufacture of a device may include depositing an adhesion layer over a substrate, depositing a seed layer upon the adhesion layer, and depositing a cobalt-platinum magnetic layer over the seed layer. Based in part on these methods of manufacture, improvements in the interfaces between the layers can be achieved after annealing with substantial improvements in the magnetic properties of the cobalt-platinum magnetic layer.

Abstract: Embodiments of the present disclosure provide systems and methods for wirelessly charging household batteries without having to remove the batteries from battery-powered user-devices, consumer electronics, or other applications to which the batteries are being deployed. In one embodiment, a wireless rechargeable battery system comprises an electrical energy storage element for a wireless rechargeable battery; a wireless receiver for the wireless rechargeable battery, wherein the wireless receiver is configured to supply electrical energy to the electrical energy storage element in a presence of a magnetic field from a charging base station; and an internal electronics circuitry for the wireless rechargeable battery, wherein the internal electronics circuitry couples the electrical energy storage element and the wireless receiver.

Abstract: Embodiments of the present disclosure relate to methods and systems for switching a magnetic field external to a magnet assembly having two permanent magnets, including a fixed permanent magnet portion and a switching permanent magnet portion, where a switching magnetic field is used to switch the magnetization of the switching permanent magnet portion, but not switch the magnetization of the fixed permanent magnet portion. In this way, the fixed permanent magnet portion has a fixed magnetization, such that the direction of magnetization of the fixed permanent magnet portion remains the same during switching of the magnetization of the switching permanent magnet portion, and the switching permanent magnet portion has a switching magnetization, such that the direction of magnetization of the switching permanent magnet portion is switched during switching of the magnetization of the switching permanent magnet portion.

Abstract: Embodiments of the present disclosure integrate magnetoelectric nanowire arrays within antenna assemblies to form ultra-compact antennas An exemplary nanowire antenna array device comprises a first electrode positioned across a second electrode, wherein an electrode gap separates the first electrode and the second electrode; and a magnetoelectric nanowire connected to the first electrode and the second electrode across the electrode gap without substrate clamping, wherein the nanowire antenna array device receives or transmits electromagnetic waves through the magnetoelectric effect.

Abstract: Nanocomposite magnetic materials, methods of manufacturing nanocomposite magnetic materials, and magnetic devices and systems using these nanocomposite magnetic materials are described. A nanocomposite magnetic material can be formed using an electro-infiltration process where nanomaterials (synthesized with tailored size, shape, magnetic properties, and surface chemistries) are infiltrated by electroplated magnetic metals after consolidating the nanomaterials into porous microstructures on planar substrates. The nanomaterials may be considered the inclusion phase, and the magnetic metals may be considered the matrix phase of the multi-phase nanocomposite.

Abstract: The present disclosure is directed towards characterizing liquids through the use of magnetic discs that rotate in response to dynamic magnetic fields. In some embodiments, a light beam is transmitted into the liquid while the magnetic discs rotate, and one or more parameters of a light beam signal associated with the transmitted light beam are identified. Various characteristics of the liquid may be detected based on the one or more parameters of the light beam signal.

Abstract: Embodiments of the present disclosure relate to methods and systems for switching a magnetic field external to a magnet assembly having two permanent magnets, including a fixed permanent magnet portion and a switching permanent magnet portion, where a switching magnetic field is used to switch the magnetization of the switching permanent magnet portion, but not switch the magnetization of the fixed permanent magnet portion. In this way, the fixed permanent magnet portion has a fixed magnetization, such that the direction of magnetization of the fixed permanent magnet portion remains the same during switching of the magnetization of the switching permanent magnet portion, and the switching permanent magnet portion has a switching magnetization, such that the direction of magnetization of the switching permanent magnet portion is switched during switching of the magnetization of the switching permanent magnet portion.

Abstract: Embodiments of the subject invention relate to an electropermanent magnet core (EPM core) having two permanent magnets (or two permanent magnet portions where each portion can have one or more permanent magnets), including a fixed permanent magnet portion and a switching permanent magnet portion, where a switching magnetic field is used to switch the magnetization of the switching permanent magnet portion, but not switch the magnetization of the fixed permanent magnet portion.

Abstract: Embodiments of a magnetic field sensor of the present disclosure includes magnetoelectric nanowires suspended above a substrate across electrodes without substrate clamping. This results in enhanced magnetoelectric coupling by reducing substrate clamping when compared to layered thin-film architectures. Accordingly, the magnetoelectric nanowires of the magnetic field sensor generate a voltage response in the presence of a magnetic field.

Abstract: Systems and methods for detecting counterfeit magnetic stripes are provided. A method can include detecting magnetic flux transitions encoded on a magnetic stripe and the variation in distances between clocking flux transitions. The distance between variations in clocking flux transitions is greater in counterfeit cards than in legitimate cards. The variations in distances can be compared with known values of legitimate cards to detect the presence of a counterfeit magnetic stripe.

Abstract: Provided herein is a magnetic apparatus for collecting superparamagnetic particles from a subject. The superparamagnetic particles are previously injected into the subject and have ligands bound thereto that are specific for one or more non-cell biomarkers. In one embodiment, the superparamagnetic particles are injected into and retrieved from a cavity such as a joint cavity. These compositions and methods allow for the sequestration and removal of inflammatory mediators, as both a diagnostic of the local immune response and a therapeutic that can reduce inflammation in the local disease environment.

Abstract: Various embodiments to mitigate the contamination of electroplated cobalt-platinum films on substrates are described. In one embodiment, a method of manufacture of a device includes depositing a diffusion barrier over a substrate, depositing a seed layer upon the diffusion barrier, and depositing a cobalt-platinum magnetic layer upon the seed layer. In a second embodiment, a method of manufacture of a device may include depositing a diffusion barrier over a substrate and depositing a cobalt-platinum magnetic layer upon the diffusion barrier. In a third embodiment, a method of manufacture of a device may include depositing an adhesion layer over a substrate, depositing a seed layer upon the adhesion layer, and depositing a cobalt-platinum magnetic layer over the seed layer. Based in part on these methods of manufacture, improvements in the interfaces between the layers can be achieved after annealing with substantial improvements in the magnetic properties of the cobalt-platinum magnetic layer.

Abstract: Disclosed are various embodiments for a system configured to characterize a magnetic response of a sample. The system can comprise an electrical source configured to generate a time-varying current supply, an excitation coil system coupled to the electrical source to generate a time-vary magnetic field for application to a sample, and a sensing coil system that senses a magnetic response of the sample in response to the time-varying magnetic field. The sensing coil system can comprise a pick-up coil and a balancing coil that can be translated or rotated. The balancing coil configured to cancel a feed-through induction signal. In another embodiment, the sensing coil system can comprise an adjustable fine-tuning coil that is configured to modify an effect of the cancellation of the feed-through induction signal.