Longitudinal to transverse relaxation time ratio (T1/T2) in unconsolidated geological materials: a perspective from 2-D borehole and laboratory NMR measurements

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autorschaft

  • Seyyed Reza Mashhadi
  • Kristina Keating
  • Mike Müller-Petke
  • Thomas Hiller
  • Stephan Costabel
  • Andres Ospina Parra
  • Denys Grombacher

Organisationseinheiten

Externe Organisationen

  • Aarhus University
  • Rutgers - The State University of New Jersey, Newark
  • Bundesanstalt für Geowissenschaften und Rohstoffe (BGR)
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummerggaf154
Seitenumfang15
FachzeitschriftGeophysical journal international
Jahrgang242
Ausgabenummer1
Frühes Online-Datum30 Apr. 2025
PublikationsstatusVeröffentlicht - Juli 2025

Abstract

This study investigates the longitudinal (T1) to transverse (T2) relaxation time ratios in unconsolidated geological materials to determine how they vary across different geological units. Assessing the T1/T2 ratio can inform about the validity of the presumed relationship between T1 and T2 relaxation times in steady-state surface nuclear magnetic resonance (NMR) modelling (i.e.T1/T2 ratio is assumed to be constant and equal to one). The T1/T2 ratio investigation is conducted by 2-D T1–T2 correlation data using laboratory and borehole NMR measurements at a Larmor frequency of 2 MHz and 430 kHz, respectively. Laboratory NMR measurements were performed on 73 sediment samples from nine sites in Denmark and Germany, and borehole NMR measurements were conducted at 59 selected depth intervals in unconsolidated geological units across eight sites in the same countries. Volumetric magnetic susceptibility of the laboratory samples was measured to evaluate the effects of magnetic susceptibility on the T1/T2 ratio. Our results indicate that the T1/T2 ratios in mineral soils and sediments are pretty similar for borehole NMR and lab NMR data sets, regardless of the geological unit. In these geological materials, the mean value of the T1/T2 ratios is 1.64 in lab-NMR and 1.82 in borehole NMR data sets. In contrast, in our in-situ borehole NMR measurements in organic peat soils, the mean value of the T1/T2 ratios was higher (i.e. 2.77), exhibiting a broader distribution ranging from 1 to 4.8. Moreover, we observed that magnetic susceptibility did not have a significant effect on the T1/T2 ratio in the investigated samples. More importantly, the findings in this study can be adopted in the modelling of steady-state surface NMR modelling routines where a constant ratio of 1 for T1/T2 is assumed when solving the Bloch equations. It is expected that updating the T1/T2 ratio can improve the accuracy of water content and relaxation time estimations derived from steady-state surface NMR measurements.

ASJC Scopus Sachgebiete

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Longitudinal to transverse relaxation time ratio (T1/T2) in unconsolidated geological materials: a perspective from 2-D borehole and laboratory NMR measurements. / Mashhadi, Seyyed Reza; Keating, Kristina; Müller-Petke, Mike et al.
in: Geophysical journal international, Jahrgang 242, Nr. 1, ggaf154, 07.2025.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

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Download

TY - JOUR

T1 - Longitudinal to transverse relaxation time ratio (T1/T2) in unconsolidated geological materials

T2 - a perspective from 2-D borehole and laboratory NMR measurements

AU - Mashhadi, Seyyed Reza

AU - Keating, Kristina

AU - Müller-Petke, Mike

AU - Hiller, Thomas

AU - Costabel, Stephan

AU - Parra, Andres Ospina

AU - Grombacher, Denys

N1 - Publisher Copyright: © The Author(s) 2025. Published by Oxford University Press on behalf of The Royal Astronomical Society.

PY - 2025/7

Y1 - 2025/7

N2 - This study investigates the longitudinal (T1) to transverse (T2) relaxation time ratios in unconsolidated geological materials to determine how they vary across different geological units. Assessing the T1/T2 ratio can inform about the validity of the presumed relationship between T1 and T2 relaxation times in steady-state surface nuclear magnetic resonance (NMR) modelling (i.e.T1/T2 ratio is assumed to be constant and equal to one). The T1/T2 ratio investigation is conducted by 2-D T1–T2 correlation data using laboratory and borehole NMR measurements at a Larmor frequency of 2 MHz and 430 kHz, respectively. Laboratory NMR measurements were performed on 73 sediment samples from nine sites in Denmark and Germany, and borehole NMR measurements were conducted at 59 selected depth intervals in unconsolidated geological units across eight sites in the same countries. Volumetric magnetic susceptibility of the laboratory samples was measured to evaluate the effects of magnetic susceptibility on the T1/T2 ratio. Our results indicate that the T1/T2 ratios in mineral soils and sediments are pretty similar for borehole NMR and lab NMR data sets, regardless of the geological unit. In these geological materials, the mean value of the T1/T2 ratios is 1.64 in lab-NMR and 1.82 in borehole NMR data sets. In contrast, in our in-situ borehole NMR measurements in organic peat soils, the mean value of the T1/T2 ratios was higher (i.e. 2.77), exhibiting a broader distribution ranging from 1 to 4.8. Moreover, we observed that magnetic susceptibility did not have a significant effect on the T1/T2 ratio in the investigated samples. More importantly, the findings in this study can be adopted in the modelling of steady-state surface NMR modelling routines where a constant ratio of 1 for T1/T2 is assumed when solving the Bloch equations. It is expected that updating the T1/T2 ratio can improve the accuracy of water content and relaxation time estimations derived from steady-state surface NMR measurements.

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KW - Statistical methods

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JO - Geophysical journal international

JF - Geophysical journal international

SN - 0956-540X

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