The use of high frequency microwaves in absolute palaeomagnetic intensity experiments

Simon Lloyd; Andy Biggin; Mimi Hill; Lennart De Groot; Neil Suttie; Joseph Morris; Harald Boehnel; John Shaw

doi:10.3389/feart.2023.1188528

The use of high frequency microwaves in absolute palaeomagnetic intensity experiments

Simon Lloyd^*, Andy Biggin, Mimi Hill, Lennart De Groot, Neil Suttie, Joseph Morris, Harald Boehnel, John Shaw

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The Microwave Palaeointensity System at the University of Liverpool has developed, over 30 years, into the current third generation version; a combined 14 GHz microwave resonant cavity and superconducting quantum interference device magnetometer integrated microwave system. The use of microwave energy minimises the bulk temperatures required to demagnetise and remagnetise palaeomagnetic material, thereby limiting the significant problem of thermo-chemical alteration of magnetic minerals. Here we review the microwave palaeointensity approach, including its development, technical details, modern usage and results. We have carried out a comprehensive analysis of 20 palaeointensity studies, published between 2008 and 2022, where data collected using the microwave system may be compared with various other methods at the site level. An assessment of microwave results revealed no statistical bias compared to thermal, and known field data. We also present results from a new controlled experiment which tests the ability of the microwave to accurately recover weak, ancient palaeointensities when strongly overprinted. We conclude that the microwave system can be used for the primary method of determining accurate absolute palaeointensities or as part of a multi-method approach, and is well suited to a wide range of material from archaeomagnetic samples to ancient rocks.

Original language	English
Article number	1188528
Pages (from-to)	1-18
Number of pages	18
Journal	Frontiers in Earth Science
Volume	11
DOIs	https://doi.org/10.3389/feart.2023.1188528
Publication status	Published - 15 Jun 2023

Bibliographical note

Funding Information:
We acknowledge earlier NERC grants NE/P00170X/1, NE/S008330/1, and NE/T012463/1 for funding for the development of the microwave system. The Natural Environment Research Council have provided almost continual support. NS was supported by Swedish Research Council grant 2020-04813.

Publisher Copyright:
Copyright © 2023 Lloyd, Biggin, Hill, De Groot, Suttie, Morris, Boehnel and Shaw.

Funding

We acknowledge earlier NERC grants NE/P00170X/1, NE/S008330/1, and NE/T012463/1 for funding for the development of the microwave system. The Natural Environment Research Council have provided almost continual support. NS was supported by Swedish Research Council grant 2020-04813.

Funders	Funder number
NERC	NE/P00170X/1, NE/S008330/1, NE/T012463/1
Natural Environment Research Council
Swedish Research Council	2020-04813
Swedish Research Council	GRANTS:17346665, 2020-04813

Keywords

geomagnetism
microwave system
palaeointensity
palaeomagnetism
rock magnetism

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10.3389/feart.2023.1188528Licence: CC BY

feart-11-1188528Final published version, 2.61 MBLicence: CC BY

Cite this

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title = "The use of high frequency microwaves in absolute palaeomagnetic intensity experiments",

abstract = "The Microwave Palaeointensity System at the University of Liverpool has developed, over 30 years, into the current third generation version; a combined 14 GHz microwave resonant cavity and superconducting quantum interference device magnetometer integrated microwave system. The use of microwave energy minimises the bulk temperatures required to demagnetise and remagnetise palaeomagnetic material, thereby limiting the significant problem of thermo-chemical alteration of magnetic minerals. Here we review the microwave palaeointensity approach, including its development, technical details, modern usage and results. We have carried out a comprehensive analysis of 20 palaeointensity studies, published between 2008 and 2022, where data collected using the microwave system may be compared with various other methods at the site level. An assessment of microwave results revealed no statistical bias compared to thermal, and known field data. We also present results from a new controlled experiment which tests the ability of the microwave to accurately recover weak, ancient palaeointensities when strongly overprinted. We conclude that the microwave system can be used for the primary method of determining accurate absolute palaeointensities or as part of a multi-method approach, and is well suited to a wide range of material from archaeomagnetic samples to ancient rocks.",

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note = "Funding Information: We acknowledge earlier NERC grants NE/P00170X/1, NE/S008330/1, and NE/T012463/1 for funding for the development of the microwave system. The Natural Environment Research Council have provided almost continual support. NS was supported by Swedish Research Council grant 2020-04813. Publisher Copyright: Copyright {\textcopyright} 2023 Lloyd, Biggin, Hill, De Groot, Suttie, Morris, Boehnel and Shaw.",

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AU - Morris, Joseph

AU - Boehnel, Harald

AU - Shaw, John

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N2 - The Microwave Palaeointensity System at the University of Liverpool has developed, over 30 years, into the current third generation version; a combined 14 GHz microwave resonant cavity and superconducting quantum interference device magnetometer integrated microwave system. The use of microwave energy minimises the bulk temperatures required to demagnetise and remagnetise palaeomagnetic material, thereby limiting the significant problem of thermo-chemical alteration of magnetic minerals. Here we review the microwave palaeointensity approach, including its development, technical details, modern usage and results. We have carried out a comprehensive analysis of 20 palaeointensity studies, published between 2008 and 2022, where data collected using the microwave system may be compared with various other methods at the site level. An assessment of microwave results revealed no statistical bias compared to thermal, and known field data. We also present results from a new controlled experiment which tests the ability of the microwave to accurately recover weak, ancient palaeointensities when strongly overprinted. We conclude that the microwave system can be used for the primary method of determining accurate absolute palaeointensities or as part of a multi-method approach, and is well suited to a wide range of material from archaeomagnetic samples to ancient rocks.

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The use of high frequency microwaves in absolute palaeomagnetic intensity experiments

Abstract

Bibliographical note

Funding

Keywords

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