Electron Nuclear Double Resonance is a technique of measuring the hyperfine and quadrupole splitting of nuclear spins that are coupled to the electron spins.

Technically Antiferro and Ferromagnetic Resonance utilize the same technique as paramagnetic resonance, but the exchange interaction leads to different physics.

Normally Electron Paramagnetic Resonance is measured by measuring the absorption of the microwaves. In some conducting samples the absorption of resonant spins can be measured by detecting a change in electrical conduction when resonant microwaves are applied to the sample. This technique is then typically referred to as Electrically Detected Magnetic Resonance (EDMR).

PELDOR, also known as DEER (Double Electron Electorn Resonance), has been demonstrated as a powerful tool for studying the topology and associated structural changes in proteins and nuclear acids.

Hydrostatic pressure has long proven to be an excellent tool to continuously tune structural, electronic and magnetic properties of matter. It offers an excellent possibility to modify magnetic exchange interactions without having to induce chemical changes to the investigated material.

Pulse techniques improve EPR resolution by using a sequence of short microwave pulses to select spin species to be detected, to separate spin interactions, and to obtain information at time domain.

Two superheterodyne computer interfaced pulsed NMR spectrometers are available for broadband applications.

The AC susceptometer for measurements at ultra-low temperatures consists of a cell totally immersed with the sample in a cell filled with liquid 3He.

This instrument is located at the MagLab's Tallahassee headquarters.

MagLab Reports, published through 2015, highlighted user and staff scientific research as well as the engineering innovation at the MagLab.

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