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

G. M. Smith; D. A. Robertson; D. R. Bolton; P. A S Cruickshank; C. Motion; J. McKay; H. El Mkami; R. Wylde; R. I. Hunter

doi:10.1049/ic.2016.0017

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

G. M. Smith, D. A. Robertson, D. R. Bolton, P. A S Cruickshank, C. Motion, J. McKay, H. El Mkami, R. Wylde, R. I. Hunter

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

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.

Original language	English
Title of host publication	IET Colloquium on Millimetre-Wave and Terahertz Engineering & Technology 2016
Place of Publication	London
Publisher	Institution of Engineering and Technology
Number of pages	5
Volume	2016
Edition	1
DOIs	https://doi.org/10.1049/ic.2016.0017
Publication status	Published - 31 Mar 2016
Event	IET Colloquium on Millimetre-Wave and Terahertz Engineering and Technology 2016 - London, United Kingdom Duration: 31 Mar 2016 → …

Conference

Conference	IET Colloquium on Millimetre-Wave and Terahertz Engineering and Technology 2016
Country/Territory	United Kingdom
City	London
Period	31/03/16 → …

Keywords

DEER spectroscopy
Electron paramagnetic resonance
Electron spin resonance
High sensitivity
MM-wave instrumentation

Access to Document

10.1049/ic.2016.0017

EP/F0390034/1 The HIPER Project: Bringing the NMR Paradigm to ESR - The HIPER Project
Smith, G. M. (PI), El Mkami, H. (CoI) & Robertson, D. (CoI)
EPSRC
1/09/08 → 31/10/12
Project: Standard

Cite this

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. (2016). Instrumentation for high sensitivity, high power, millimetre wave, electron paramagnetic resonance. In IET Colloquium on Millimetre-Wave and Terahertz Engineering & Technology 2016 (1 ed., Vol. 2016). Institution of Engineering and Technology. https://doi.org/10.1049/ic.2016.0017

@inproceedings{dfb9ea459c3946f09fafb95137eff55d,

title = "Instrumentation for high sensitivity, high power, millimetre wave, electron paramagnetic resonance",

abstract = "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.",

keywords = "DEER spectroscopy, Electron paramagnetic resonance, Electron spin resonance, High sensitivity, MM-wave instrumentation",

author = "Smith, {G. M.} and Robertson, {D. A.} and Bolton, {D. R.} and Cruickshank, {P. A S} and C. Motion and J. McKay and {El Mkami}, H. and R. Wylde and Hunter, {R. I.}",

note = "The HIPER spectrometer was funded under the UKRC Basic Technology program (Grant EP/F039034/1; IET Colloquium on Millimetre-Wave and Terahertz Engineering and Technology 2016 ; Conference date: 31-03-2016",

year = "2016",

month = mar,

day = "31",

doi = "10.1049/ic.2016.0017",

language = "English",

volume = "2016",

booktitle = "IET Colloquium on Millimetre-Wave and Terahertz Engineering & Technology 2016",

publisher = "Institution of Engineering and Technology",

address = "United Kingdom",

edition = "1",

}

Smith, GM , Robertson, DA, Bolton, DR, Cruickshank, PAS, Motion, C, McKay, J, El Mkami, H, Wylde, R & Hunter, RI 2016, Instrumentation for high sensitivity, high power, millimetre wave, electron paramagnetic resonance. in IET Colloquium on Millimetre-Wave and Terahertz Engineering & Technology 2016. 1 edn, vol. 2016, Institution of Engineering and Technology, London, IET Colloquium on Millimetre-Wave and Terahertz Engineering and Technology 2016, London, United Kingdom, 31/03/16. https://doi.org/10.1049/ic.2016.0017

Instrumentation for high sensitivity, high power, millimetre wave, electron paramagnetic resonance. / Smith, G. M.; Robertson, D. A.; Bolton, D. R. et al.
IET Colloquium on Millimetre-Wave and Terahertz Engineering & Technology 2016. Vol. 2016 1. ed. London: Institution of Engineering and Technology, 2016.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

TY - GEN

T1 - Instrumentation for high sensitivity, high power, millimetre wave, electron paramagnetic resonance

AU - Smith, G. M.

AU - Robertson, D. A.

AU - Bolton, D. R.

AU - Cruickshank, P. A S

AU - Motion, C.

AU - McKay, J.

AU - El Mkami, H.

AU - Wylde, R.

AU - Hunter, R. I.

N1 - The HIPER spectrometer was funded under the UKRC Basic Technology program (Grant EP/F039034/1

PY - 2016/3/31

Y1 - 2016/3/31

N2 - 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.

AB - 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.

KW - DEER spectroscopy

KW - Electron paramagnetic resonance

KW - Electron spin resonance

KW - High sensitivity

KW - MM-wave instrumentation

U2 - 10.1049/ic.2016.0017

DO - 10.1049/ic.2016.0017

M3 - Conference contribution

AN - SCOPUS:84975090480

VL - 2016

BT - IET Colloquium on Millimetre-Wave and Terahertz Engineering & Technology 2016

PB - Institution of Engineering and Technology

CY - London

T2 - IET Colloquium on Millimetre-Wave and Terahertz Engineering and Technology 2016

Y2 - 31 March 2016

ER -

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

Abstract

Conference

Keywords

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Projects

EP/F0390034/1 The HIPER Project: Bringing the NMR Paradigm to ESR - The HIPER Project

Cite this