JpGU-AGU Joint Meeting 2017

講演情報

[EE] 口頭発表

セッション記号 S (固体地球科学) » S-EM 固体地球電磁気学

[S-EM18] [EE] General Contributions in Geomagnetism, Paleomagnetism, and Rockmagnetism

2017年5月21日(日) 10:45 〜 12:15 301B (国際会議場 3F)

コンビーナ:小田 啓邦(産業技術総合研究所地質情報研究部門)、望月 伸竜(熊本大学大学院先導機構)、Joshua M Feinberg(University of Minnesota)、Myriam Annie Claire Kars(Center for Advanced Marine Core Research)、座長:Roberts Andrew(Australian National University)、座長:Zhao Xiangyu(National Institute of Polar Research)、座長:小田 啓邦(産業技術総合研究所地質情報研究部門)

11:00 〜 11:20

[SEM18-13] New measurement protocols for hysteresis reversal curves and identification of magnetic mineral components

★招待講演

*Andrew P Roberts1Xiang Zhao1David Heslop1 (1.Australian National University)

キーワード:Geomagnetism, Paleomagnetism, Rockmagnetism

High-resolution first-order reversal curve (FORC) diagrams are being used increasingly in rock and environmental magnetism, including for detection of biomagnetic signals in sediments. Resolution can be a major barrier to obtaining high-quality FORC diagrams and time-consuming measurements that employ small field steps are necessary to resolve the finest features of a FORC distribution. We have developed a new experimental protocol with irregularly spaced field steps that allows different parts of a FORC diagram to be measured at different resolutions. Larger numbers of measurements can, therefore, be made in key regions of a FORC distribution to resolve diagnostic features at higher resolution. Specification of the field steps in the irregular grid is based on measurement of a major hysteresis loop; no a priori knowledge concerning the underlying FORC distribution is required. FORC diagrams obtained with conventional measurements and with our new measurement protocol give consistent results. We have also extended the applicability of FORC-type diagrams through use of a series of hysteresis measurements that provide information about remanent, induced, transient, and transient-free magnetization components. These measurements, and differences between measurement types, enable production of 6 FORC-like diagrams with only double the number of measurements needed for a conventional FORC measurement. These diagrams enable discrimination between magnetic signatures associated with each domain state. When analyzing samples with complex magnetic mineral mixtures, contrasting domain state signatures are mixed in a traditional FORC diagram, but these signatures can be identified individually with the 6 diagrams discussed here. The ability to make different FORC measurements and to identify separately each magnetic component in a conventional FORC diagram by investigating different magnetization types can provide much-improved understanding of the information provided by FORC diagrams. The diagnostic information provided by these additional FORC-type diagrams should assist substantially in magnetic unmixing of complex samples and in quantitative mineral magnetic interpretation.