Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Exploration Geophysics Exploration Geophysics Society
Journal of the Australian Society of Exploration Geophysicists
RESEARCH ARTICLE

Remote remanence estimation (RRE)

David A. Pratt 1 2 K. Blair McKenzie 1 Tony S. White 1
+ Author Affiliations
- Author Affiliations

1 Tensor Research Pty Ltd, PO Box 8159, Greenwich, NSW 2065, Australia.

2 Corresponding author. Email: David.Pratt@tensor-research.com.au

Exploration Geophysics 45(4) 314-323 https://doi.org/10.1071/EG14031
Submitted: 19 March 2014  Accepted: 2 August 2014   Published: 17 September 2014

Abstract

The remote determination of magnetic remanence in rocks is a method that has largely been ignored because of the ambiguity associated with the estimation of both the Koenigsberger ratio and remanent magnetisation direction. Our research shows that the resultant magnetisation direction can be derived directly through inversion of magnetic data for an isolated magnetic anomaly from a compact magnetic source. The resultant magnetisation direction is a property of the target magnetic rocks and a robust inversion parameter. The departure angle of the resultant magnetisation vector from that of the inducing magnetic field is an important indicator of the existence of remanent magnetisation and the inversion process can detect departures that are not easily detected by visual inspection. This departure angle is called the apparent resultant rotation angle or ARRA.

The induced field vector, remanent magnetisation vector and resultant magnetisation vector lie on the plane of a great circle. We find the intersection of the transformed polar wander vector trace with the great circle plane to obtain one or more possible solutions for the remanent magnetisation vector. Geological deduction will normally allow us to reduce the ambiguity for multiple solutions to obtain the most likely remanent magnetisation direction. Once the remanent magnetisation direction is established, it is then possible to determine the Koenigsberger ratio and magnetic susceptibility for the target.

We illustrate the methodology using survey data over the Black Hill Norite which also has extensive palaeomagnetic data available for comparison with the inversion results. We then apply the remote remanence estimation (RRE) method to a systematic study of a large number of intrusive pipes in the Thomson Orogen, New South Wales. The corrected magnetic susceptibility and remanence properties, spatial distribution and underlying uncertainties are evaluated for their potential use by diamond explorers. The additional information assists with differentiating kimberlites from other intrusive pipes based on age and remanence properties.

Key words: inversion, kimberlite, magnetisation, remanence, resultant, susceptibility.


References

Caratori Tontini, F., and Pedersen, L. B., 2008, Interpretating magnetic data using integral moments: Geophysical Journal International, 174, 815–824
Interpretating magnetic data using integral moments:Crossref | GoogleScholarGoogle Scholar |

Clark, D. A., 1997, Magnetic petrophysics and magnetic petrology: aids to geological interpretation of magnetic surveys: AGSO Journal of Australian Geology & Geophysics, 17, 83–103
| 1:CAS:528:DyaK2sXit12luro%3D&md5=5d3163db7542ce631ed20a150b08e4caCAS |

Clark, D. A., 2012, New methods for interpretation of magnetic vector and gradient tensor data I: eigenvector analysis and the normalised source strength: Exploration Geophysics, 43, 267–282
New methods for interpretation of magnetic vector and gradient tensor data I: eigenvector analysis and the normalised source strength:Crossref | GoogleScholarGoogle Scholar |

Clark, D. A., 2013, New methods for interpretation of magnetic vector and gradient tensor data II: Application to the Mount Leyshon Anomaly, Queensland: Exploration Geophysics, 44, 114–127
New methods for interpretation of magnetic vector and gradient tensor data II: Application to the Mount Leyshon Anomaly, Queensland:Crossref | GoogleScholarGoogle Scholar |

Clark, D. A., 2014, Methods for determining remanent and total magnetization of magnetic sources – a review: Exploration Geophysics, 45, 271–304
Methods for determining remanent and total magnetization of magnetic sources – a review:Crossref | GoogleScholarGoogle Scholar |

Clark, D. A., and Lackie, M. A., 2003, Palaeomagnetism of the Early Permian Mount Leyshon Intrusive Complex and the Tuckers Igneous Complex, North Queensland, Australia: Geophysical Journal International, 153, 523–547
Palaeomagnetism of the Early Permian Mount Leyshon Intrusive Complex and the Tuckers Igneous Complex, North Queensland, Australia:Crossref | GoogleScholarGoogle Scholar |

Cordani, R., and Shukowsky, W., 2009, Virtual Pole from magnetic Anomaly (VPMA): a procedure to estimate the age of a rock from its magnetic anomaly only: Journal of Applied Geophysics, 69, 96–102
Virtual Pole from magnetic Anomaly (VPMA): a procedure to estimate the age of a rock from its magnetic anomaly only:Crossref | GoogleScholarGoogle Scholar |

Ellis, R. G., de Wet, B., and MacLeod, I. N., 2012, Inversion of magnetic data for remanent and induced sources: ASEG-PESA 22nd International Geophysical Conference and Exhibition, Extended Abstracts, 4 pp.

Foss, C. A., and McKenzie, K. B., 2006, Inversion of anomalies due to remanent magnetization – an example from the Black Hill Norite of South Australia: ASEG AESC2006, Extended Abstracts, 9 pp.

Foss, C. A., and McKenzie, K. B., 2011, Inversion of anomalies due to remanent magnetization: an example from the Black Hill Norite of South Australia: Australian Journal of Earth Sciences, 58, 391–405
Inversion of anomalies due to remanent magnetization: an example from the Black Hill Norite of South Australia:Crossref | GoogleScholarGoogle Scholar |

Glen, R. A., Saeed, A., Hegarty, R., Percival, I. G., Bodorkos, S., and Griffin, W. L., 2010, Preliminary zircon data and tectonic framework for the Thomson Orogen, northwestern NSW: Geological Survey of NSW, Exploration in the House, Parliament House, Macquarie St., 20 pp., 6 fig.

Grant, F. S., and West, G. F., 1965, Interpretation theory in applied geophysics: McGraw-Hill.

Li, Y., Shearer, S., Haney, M., and Dannemiller, N., 2010, Comprehensive approaches to the inversion of magnetic data affected by remanent magnetization: Geophysics, 75, L1–L11
Comprehensive approaches to the inversion of magnetic data affected by remanent magnetization:Crossref | GoogleScholarGoogle Scholar |

MacLeod, I. N., and Ellis, R. G., 2013, Magnetic vector inversion, a simple approach to the challenge of varying direction of rock magnetization: ASEG forum on The Application of Remanent Magnetization and Self-Demagnetisation Estimation to Mineral Exploration, Extended Abstracts, 41–46.

McKenzie, K. B., Hillan, D., and Foss, C. A., 2012, An improved search for magnetization direction: ASEG 22nd International Conference and Exhibition, Extended Abstracts, 4 pp.

Medeiros, W. E., and Silva, J. B., 1995, Simultaneous estimation of total magnetization direction and 3-D spatial orientation: Geophysics, 60, 1365–1377
Simultaneous estimation of total magnetization direction and 3-D spatial orientation:Crossref | GoogleScholarGoogle Scholar |

Merrill, R. T., McElhinny, W., and McFadden, P. L., 1996, The magnetic field of the Earth: Academic Press.

Morris, W., Ugalde, H., and Thompson, V., 2007, Magnetic remanence constraints on magnetic inversion models: The Leading Edge, 26, 960–964
Magnetic remanence constraints on magnetic inversion models:Crossref | GoogleScholarGoogle Scholar |

Pratt, D. A., McKenzie, K. B., and White, A. S., 2012, The remote determination of magnetic remanence: ASEG-PESA 22nd International Geophysical Conference and Exhibition, Extended Abstracts, 5 pp.

Rajagopalan, S., Clark, D. A., and Schmidt, P. W., 1995, Magnetic mineralogy of the Black Hill Norite and its aeromagnetic and palaeomagnetic implications: Exploration Geophysics, 26, 215–220
Magnetic mineralogy of the Black Hill Norite and its aeromagnetic and palaeomagnetic implications:Crossref | GoogleScholarGoogle Scholar |

Schmidt, P. W., and Clark, D. A., 1998, The calculation of magnetic components and moments from TMI: a case study from the Tuckers igneous complex, Queensland: Exploration Geophysics, 29, 609–614
The calculation of magnetic components and moments from TMI: a case study from the Tuckers igneous complex, Queensland:Crossref | GoogleScholarGoogle Scholar |

Schmidt, P. W., Clark, D. A., and Rajagopalan, S., 1993, A historical perspective of the Early Palaeozoic APWP of Gondwana: new results from the Early Ordovician Black Hill Norite of South Australia: Exploration Geophysics, 24, 257–262
A historical perspective of the Early Palaeozoic APWP of Gondwana: new results from the Early Ordovician Black Hill Norite of South Australia:Crossref | GoogleScholarGoogle Scholar |

Smith, M. L., Pillans, B. J., and McQueen, K. G., 2009, Paleomagnetic evidence for periods of intense oxidation weathering, McKinnons mine, Cobar, New South Wales: Australian Journal of Earth Sciences, 56, 201–212
Paleomagnetic evidence for periods of intense oxidation weathering, McKinnons mine, Cobar, New South Wales:Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXlsVamt7c%3D&md5=227a2fe16a99e050b71ed58b61064b94CAS |

Turner, S. P., 1991, Late-orogenic, mantle-derived, bi-modal magmatism in the southern Adelaide Foldbelt, South Australia: Ph.D. thesis, University of Adelaide.