Provided is a long-wave infrared detecting element including a magnetic field generator configured to generate a magnetic field, a substrate provided on the magnetic field generator, a magnetic-electric converter that is spaced apart from the substrate and configured to generate an electrical signal based on the magnetic field generated by the magnetic field generator, and an support unit that is provided on the substrate and supports the magnetic-electric converter in a state in which the magnetic-electric converter is spaced apart from the substrate, the support unit being configured to generate heat by absorbing incident infrared radiation, wherein the electrical signal changes corresponding to temperature changes of the magnetic-electric converter based on the incident infrared radiation directly absorbed in the magnetic-electric converter and temperature changes of the magnetic-electric converter based on the incident infrared radiation absorbed in the support unit.

A physical state measurement apparatus includes a main solid material which generates fluorescence by excitation light from a light source part. A microwave application part applies microwaves to the main solid material so as to control an electron state of the main solid material. A detection part detects the physical state of an object to be measured by the fluorescence from the main solid material. A feedback part has a solid material for feedback and a control part and detects a difference in amplitude between operating points on a low-frequency side and a high-frequency side of a lowering portion of a spectrum amplitude centered on a resonance frequency of an electron spin resonance spectrum of fluorescence from the solid material for feedback and feedback-controls the microwave application part such that the difference becomes zero.

A magnetic sensor includes a semiconductor element, a lead frame, a bonding wire, and a package. The lead frame includes a die pad to which the semiconductor element is attached and an external connection lead. The bonding wire connects the external connection lead with the semiconductor element. The package seals the semiconductor element, the die pad, the external connection pad, and the bonding wire. The package is made of epoxy-based resin. The lead frame further includes a projecting portion extending from the die pad, the projecting portion is exposed from the package at a position different from a position of the external connection lead, and a partial surface of the projecting portion which contacts with the package is made of material having a higher ionization tendency than an ionization tendency of silver.

Disclosed herein are detection methods that use magnetic nanoparticles (MNPs) to allow molecules to be identified. Embodiments of this disclosure include methods of using magnetic sensors (e.g., magnetoresistive sensors) to detect temperature-dependent magnetic fields (or changes in magnetic fields) emitted by MNPs, and, specifically to distinguish between the presence and absence of magnetic fields emitted, or not emitted, by MNPs at different temperatures selected to take advantage of knowledge of how the MNPs' magnetic properties change with temperature. Embodiments disclosed herein may be used for nucleic acid sequencing, such as deoxyribonucleic acid (DNA) sequencing.

An arrangement of at least two adjacently arranged layer structures is provided for a magnetoresistive magnetic field sensor. Each layer structure has at least one antiferromagnetic layer, and a first ferromagnetic layer with a first magnetic moment. Exchange coupling is present between the antiferromagnetic layer and the first ferromagnetic layer. A second ferromagnetic layer with a second magnetic moment is included, wherein the second ferromagnetic layer is antiparallel coupled to the first ferromagnetic layer via a non-magnetic coupling layer arranged between the first and second ferromagnetic layers. The magnetisation of the corresponding first and corresponding second ferromagnetic layers of the adjacently arranged layer structures differs from one another, and in particular is of substantially mutually opposed orientation. Also provided is a magnetoresistive magnetic field sensor with such an arrangement of layer structures and a method for producing the arrangement of layer structures and the magnetoresistive magnetic field sensor.

A magnetic field measurement system includes a wearable device having a plurality of wearable sensor units. Each wearable sensor unit includes a plurality of magnetometers and a magnetic field generator configured to generate a compensation magnetic field configured to actively shield the plurality magnetometers from ambient background magnetic fields. A strength of a fringe magnetic field generated by the magnetic field generator of each of the wearable sensor units is less than a predetermined value at the plurality of magnetometers of each wearable sensor unit included in the plurality of wearable sensor units.

An objective of the present invention is to provide a biomagnetism measurement device capable of three-dimensionally acquiring magnetism information of a living body with ease. This biomagnetism measurement device (101) is for measuring biomagnetism using a plurality of magnetic sensors (1) at the same time. The plurality of magnetic sensors (1) is retained by a retaining part (10) (a first retaining portion [11] and a second retaining portion [12]) so as to have different measurement directions. Furthermore, the retaining part (10) (the first retaining portion [11] and the second retaining portion [12]) has arranged thereon the plurality of magnetic sensors (1) so as to enable biomagnetism to be measured at a plurality of sites at the same time. The magnetic sensor (1) comprises a means for detecting the biomagnetism in a temperature environment commensurate with normal temperature.

A magnetoresistive magnetic field probe with rotating electromechanical modulator (1) comprises: a bulk cylindrical base (11), wherein the bulk cylindrical base (11) has a cavity structure, and a center axis of the bulk cylindrical base (11) overlaps with a z-axis of a cylindrical coordinate system; a first magnetic tile (12) and a second magnetic tile (13) attached to an outer side wall of the bulk cylindrical base (11); and a magnetoresistive sensor (14) and a reference signal generator (15) located on the center axis of the bulk cylindrical base (11). During operation, the bulk cylindrical base (11) rotates about the z-axis at a frequency f, and the first magnetic tile (12) and the second magnetic tile (13) modulate an external magnetic field into a sensed magnetic field having a frequency 2f, and a measurement signal having a frequency 2f is output via the magnetoresistive sensor (14). The reference signal generator (15) outputs a reference signal having a frequency 2f. The reference signal and the measurement signal are demodulated by an external processing circuit (4) to output a magnetic field value, so as to provide a measurement of the external magnetic field with superior signal-to-noise ratio. Through adding a detachable rotating sleeve to the magnetoresistive sensor (14), superior signal-to-noise ratio measurement of the external magnetic fields can be realized. This invention is small in size with a simple structure, and the complexity of the process is also greatly reduced, enabling lower cost.

A sensor element based on a magneto-thermoelectric effect and realizing method thereof are provided, the sensor element includes a plurality of thermoelectric elements having an angular structure and are located in a magnetic field; the thermoelectric element is made of magnetic material having a thermoelectric effect, and includes a first side, a second side, and an angular part formed by connecting the two sides; the angular part is provided with a heating device; and the temperature in the region where the other end of the first side and the second side are located are less than or equal to the ambient temperature.

An apparatus and a method for indirectly cooling a superconducting quantum interference device (SQUID) are provided. The apparatus includes an outer container extending in a vertical direction; a metallic inner container inserted into the outer container to store a liquid coolant, the metal inner container including a top plate; a SQUID sensor module disposed between a bottom surface of the outer container and a bottom surface of the inner container; a heat transfer pillar adapted to cool the SQUID sensor module, the heat transfer pillar having one end connected to the bottom surface of the inner container and the other end directly or indirectly connected to the SQUID sensor module; a magnetic shield part formed of a superconductor covering a top surface of the SQUID sensor module; and a heat conduction plate being in thermal contact with the other end of the heat transfer pillar.