A magnetic field causing a difference of energy level between different spin states in the sample can be applied, a spin transition in the material can be triggered by exposing the sample to electromagnetic radiation of an energy level corresponding to the difference in energy level between the different spin states, a sensing surface of a superconducting element can be exposed to a magnetic field of the spins in the sample, the spin transition can cause, via kinetic inductance, a change in electromagnetic waves carried by the superconducting element which can be detected. A magnetic field component normal to the sensing surface, below a certain magnetic field threshold, can be applied to favor sensitivity.

A method and a device for detecting substances and their concentrations in a mixture using magnetic resonance, containing one or more markers deposited on a surface of a carrier in contact with the mixture, wherein the marker is a substance that through intermolecular interactions causes a predetermined orientation of molecules for at least one of the mixture components.

A 3D microwave sensor includes a cloud of particles, e.g., rubidium 87 atoms. A laser system produces: a first probe beam directed through the particle cloud along a first path; a second probe beam directed through the particle cloud along a second path that intersects the first path to define a Rydberg intersection; a first coupling beam that counterpropagates with respect to the first probe beam along the first path; and a second coupling beam that counterpropagates with respect to the second probe beam along the second path. A spectrum analyzer characterizes the microwave field strength at the Rydberg intersection. The laser beams can be steered to move the Rydberg intersection within the particle cloud to compile a microwave field strength distribution in the particle cloud.

A 3D microwave sensor includes a cloud of particles, e.g., rubidium 87 atoms. A laser system produces: a first probe beam directed through the particle cloud along a first path; a second probe beam directed through the particle cloud along a second path that intersects the first path to define a Rydberg intersection; a first coupling beam that counterpropagates with respect to the first probe beam along the first path; and a second coupling beam that counterpropagates with respect to the second probe beam along the second path. A spectrum analyzer characterizes the microwave field strength at the Rydberg intersection. The laser beams can be steered to move the Rydberg intersection within the particle cloud to compile a microwave field strength distribution in the particle cloud.

The present invention relates to implantable resonator systems for deep-tissue EPR oximetry and methods of using thereof. The implantable resonator of the present disclosure includes a resonator with an implantable end, a transmission line, and an external end, wherein the external end further includes a coupling loop operably connected to a coupling device. The coupling device includes a clamping mechanism to ensure proper alignment of the coupling loop. The implantable resonator may be used to monitor a tissue.

The present invention relates to implantable resonator systems for deep-tissue EPR oximetry and methods of using thereof. The implantable resonator of the present disclosure includes a resonator with an implantable end, a transmission line, and an external end, wherein the external end further includes a coupling loop operably connected to a coupling device. The coupling device includes a clamping mechanism to ensure proper alignment of the coupling loop. The implantable resonator may be used to monitor a tissue.

Microwave resonance cavities and associated methods and apparatus are described. In one example, a cavity (100) comprises a first and a second input port (102, 104) for inputting microwave radiation at a first and a second frequency respectively. The microwave radiation at the first frequency may be to excite a sample in the cavity whereas the microwave radiation at the second frequency may be to interrogate a sample in the cavity for analysis. The cavity has dimensions such that it resonates at both the first and the second frequency.

Microwave resonance cavities and associated methods and apparatus are described. In one example, a cavity (100) comprises a first and a second input port (102, 104) for inputting microwave radiation at a first and a second frequency respectively. The microwave radiation at the first frequency may be to excite a sample in the cavity whereas the microwave radiation at the second frequency may be to interrogate a sample in the cavity for analysis. The cavity has dimensions such that it resonates at both the first and the second frequency.

Embodiments of the present disclosure describe an electrochemical-electron paramagnetic resonance (EC-EPR) cell comprising a flat cell member positioned between a top capillary member and a bottom capillary member; a working electrode including a metal wire section configured to be housed within the top capillary member, and a flat metal section attached to the metal wire section; and a reference electrode and counter electrode configured to be housed within the top capillary member; wherein the flat metal section is dimensioned to be inserted, along with a catalyst and electrolyte, into the flat cell member; wherein the flat cell member is configured to orient the flat metal section of the working electrode and catalyst in a region of an electron paramagnetic resonance cavity in which a magnetic component of a microwave field is a maximum.

Embodiments of the present disclosure describe an electrochemical-electron paramagnetic resonance (EC-EPR) cell comprising a flat cell member positioned between a top capillary member and a bottom capillary member; a working electrode including a metal wire section configured to be housed within the top capillary member, and a flat metal section attached to the metal wire section; and a reference electrode and counter electrode configured to be housed within the top capillary member; wherein the flat metal section is dimensioned to be inserted, along with a catalyst and electrolyte, into the flat cell member; wherein the flat cell member is configured to orient the flat metal section of the working electrode and catalyst in a region of an electron paramagnetic resonance cavity in which a magnetic component of a microwave field is a maximum.