Instrumentation for high sensitivity, high power, millimetre wave, electron paramagnetic resonance

Instrumentation for high sensitivity, high power, millimetre wave, electron paramagnetic resonance

Pulsed Electron Paramagnetic Resonance (EPR) is now a standard magnetic resonance characterisation technique used in the analysis of paramagnetic defects, transition metal complexes and organic radicals in materials and biomolecular systems. Pulsed EPR is now commonly used to measure distances betwe...

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Bibliographic Details
Published in:IET Colloquium on Millimetre-Wave and Terahertz Engineering & Technology 2016 p. 8
Main Authors: Smith, G.M, Robertson, D.A, Bolton, D.R, Cruickshank, P.A.S, Motion, C, McKay, J, El Mkami, H, Wylde, R, Hunter, R.I
Format: Conference Proceeding
Language:English
Published: Stevenage, UK IET 2016
The Institution of Engineering & Technology
Subjects:
Coordination compounds
Defects
Deoxyribonucleic acid
DNA
Electron paramagnetic resonance
Electron paramagnetic resonance and relaxation (condensed matter)
Electron spin
Instruments
Magnetic resonance
Proteins
Ribonucleic acid
RNA
Sensitivity
Transition metals
transition metal complex
biomolecular system
RNA
pulsed electron paramagnetic resonance
power 1 kW
organic radical
pulsed EPR
precise timing control
paramagnetic resonance
DNA
frequency 94 GHz
millimetre wave electron paramagnetic resonance
magnetic resonance characterisation technique
coherent mm-wave pulse
cryogenic sample
paramagnetic defect
frequency 10 GHz
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Summary:Pulsed Electron Paramagnetic Resonance (EPR) is now a standard magnetic resonance characterisation technique used in the analysis of paramagnetic defects, transition metal complexes and organic radicals in materials and biomolecular systems. Pulsed EPR is now commonly used to measure distances between spin labels or transition metals in proteins, RNA and DNA, to evaluate structure, conformational changes and binding. Most EPR measurements have traditionally been undertaken at frequencies of 10 GHz at fields of 0.34 T. However, recently we have shown that there are substantial advantages to moving to higher fields of 3.4 T and measuring at 94 GHz at power levels of 1 kW. Sensitivity can improve by orders of magnitude - and substantial gains can be made in time resolution. Such systems require flexible, and precise timing control of coherent mm-wave pulses at kW power levels, and delivery of those pulses to samples at cryogenic samples, followed by coherent detection of signals at sub-nW power levels with low deadtime. In this paper we briefly outline the major applications, technical requirements and opportunities for mm-wave EPR, before briefly outlining the critical mm-wave components in a low deadtime, mm-wave EPR system that currently operates with state-of-the-art performance.
ISBN:1785612220
9781785612220
DOI:10.1049/ic.2016.0017