Abstract
NMR experiments are ideally carried out in well-controlled magnetic fields. When samples of natural porous materials are studied, the situation can be complicated if the sample itself contains magnetic components, giving rise to internal magnetic fields in the pore space that modulate the externally applied fields. If not properly accounted for, the internal fields can lead to misinterpretation of relaxation, diffusion, or imaging data. To predict the potential effect of internal fields, and develop effective mitigation strategies, it is important to develop a quantitative understanding of the magnitude and distribution of internal fields occurring in natural porous media. To develop such understanding, we employ scanning SQUID microscopy, a technique that can detect magnetic field variations very accurately at high spatial resolution (∼3 μm). We prepared samples from natural unconsolidated aquifer material, and scanned areas of about 200 × 200 μm in a very low background magnetic field of ∼2 μT. We found large amplitude variations with a magnitude of about 2 mT, across a relatively long spatial scale of about 200 μm, that are associated with a large magnetic grain (>50 μm radius) with a strong magnetic remanence. We also detected substantial variations exceeding 60 μT on small spatial scales of about ∼10 μm. We attribute these small-scale variations to very fine-grained magnetic material. Because we made our measurements at very low background field, the observed variations are not induced by the background field but due to magnetic remanence. Consequently, the observed internal fields will affect even low-field NMR experiments.
| Original language | English |
|---|---|
| Pages (from-to) | 10-17 |
| Number of pages | 8 |
| Journal | Journal of Magnetic Resonance |
| Volume | 242 |
| DOIs | |
| State | Published - May 2014 |
Bibliographical note
Funding Information:We thank Eric Spanton for his support with the SQUID measurements, and the Fisher lab at Stanford for their support with measurements to determine the temperature dependence of magnetic moment. JW was supported by a grant from the National Science Foundation (Grant No. 0911234). BK was supported by EC Grant No. FP7-PEOPLE-2012-CIG-333799, FENA-MARCO Contract No. 0160SMB958, DARPA No. C10J10834, and NSF DMR-0803974. The scanning SQUID measurement technique was developed with support from the NSF-sponsored Center for Probing the Nanoscale at Stanford, NSF-NSEC 0830228, and NSF IMR-MIP 0957616. The measurements of temperature dependence were carried out on a MPMS system, Quantum Design Inc., California, US. The synthetic sand used for the reference sample was obtained from Wedron Silica Co., Illinois, US. We thank the anonymous reviewers for their comments that helped improve this manuscript.
Funding
We thank Eric Spanton for his support with the SQUID measurements, and the Fisher lab at Stanford for their support with measurements to determine the temperature dependence of magnetic moment. JW was supported by a grant from the National Science Foundation (Grant No. 0911234). BK was supported by EC Grant No. FP7-PEOPLE-2012-CIG-333799, FENA-MARCO Contract No. 0160SMB958, DARPA No. C10J10834, and NSF DMR-0803974. The scanning SQUID measurement technique was developed with support from the NSF-sponsored Center for Probing the Nanoscale at Stanford, NSF-NSEC 0830228, and NSF IMR-MIP 0957616. The measurements of temperature dependence were carried out on a MPMS system, Quantum Design Inc., California, US. The synthetic sand used for the reference sample was obtained from Wedron Silica Co., Illinois, US. We thank the anonymous reviewers for their comments that helped improve this manuscript.
| Funders | Funder number |
|---|---|
| National Science Foundation | 0911234, 0957616 |
| European Commission |
Keywords
- Internal magnetic fields
- Porous media
- SQUID