Investigating the reasons for the failure of palaeointensity experiments:: a study on historical lava flows from Mt. Etna (Italy)

A refined palaeointensity experiment, accompanied by rock-magnetic studies, has been carried out on six lava flows from 1910 and 1928 from Mt. Etna. The Purpose of the Study was to try to understand why these very young basaltic flows are generally tillable to provide it correct estimate of the magnitude of the ambient magnetic field during flow cooling. Susceptibility versus temperature curves and ore microscopic studies show that 3 types of magnetic minerals (phases 'h'. 'm' and 'l') are present in these flocks. some samples containing a single largely dominant magnetic phase while others contain it mixture of several phases. Phase 'h' is a thermally stable, near magnetite phase resulting from titanomagnetite oxyexsolution. Phase 'l' is a thermally stable titanomagnetite with a Curie temperature of approximately 200 C. Phase 'm' is a titanomagnetite phase Of Curie temperature between 450 490 C which is unstable at temperatures above 400 C. In addition to file usual reliability checks of the Thellier method (NRM-TRM linearity, pTRM checks), Our palaeointensity experiments included additional heating allowing determination of the MD or PSD-SD character of each pTRM and determination of CRM or transdomain remanenees possibly acquired during heating. From the 28 samples studied 20 provide a linear NRM-TRM plot over about 1/4 or more of total NRM. However, only six of them, all containing near-magnetite its a single phase, display positive pTRM checks. Nevertheless, these six samples yield it mean palaeointensity of about 52 muT which exceeds the real field palaeomagnitude (42 muT) by some 25 per cent. The reasons for this almost-total Failure of palaeointensity experiments are diverse, For samples with a dominant 'l' phase, pTRMs present it behaviour typical of large MD grains. with as much as 1/3 of remanence with unblocking temperatures exceeding the blocking range. No CRM is acquired. Yet a remanence does develop during heating in it field (followed by cooling in zero field). We suggest that this remanence is it transdomain remanence resulting from domain rearrangements. These two observations are in conflict with some of the basic requirements of the Thellier method. Phase 'm' seems chemically stable LIP to 400 ('but pTRM changes start at lower temperatures. This thermal instability and the development of a significant transdomain remanence seem to be the causes of the failure of palaeointensity experiments, The reason for the rather large (and quite unexpected) error in the average palaeointensity provided by the samples containing only a near magnetite (phase 'h') may lie in the fact that the low to medium temperature pTRMs. which represent a significant fraction of the total TRM. seem to be carried by small MD particles. In conclusion, several modifications of the Thellier method are proposed.