Advances in Geophysics Applied to the Search for Banded Iron Formation-Related, High-Grade Hematite Iron Ore
Marcus Flis, 2008. "Advances in Geophysics Applied to the Search for Banded Iron Formation-Related, High-Grade Hematite Iron Ore", Banded Iron Formation-Related High-Grade Iron Ore, Steffen Hagemann, Carlos Alberto Rosière, Jens Gutzmer, Nicolas J. Beukes
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The most common magnetic mineral is magnetite, which is widespread in banded iron formations (BIFs). It is no surprise that the first application of geophysics in mineral exploration was the search for iron. The method used to detect magnetic minerals, the magnetic method, has had a long and involved gestation period. From its first reported use as a "bump finder," the magnetic method has evolved to become the mainstay of iron exploration. This evolution has mirrored the technological revolution that morphed from the industrial revolution. Magnetometers developed from simple analogue instruments, including compasses and torsion balances, to electronic and atomic-based units in the form of proton precession and optically pumped instruments. A further boost in the magnetometer's usefulness was provided with the development of fast acquisition systems and safe airborne platforms. This was further aided by both the exponential rise in computer power and the advent of a Global Positioning System (GPS). The result has been a geophysical method that can accurately, quickly, and cheaply map the distribution of magnetite in rocks to a level of accuracy that has seen the magnetic method move from bump finder to geologic mapping tool.
High-grade hematite mineralization is generally difficult to directly detect by the magnetic method. The lithologic associations, structural settings, and evidence of geologic processes, however, can be readily mapped out by the method. As the understanding of iron ore genesis evolves, the method can be used to directly test aspects of the genesis model, often on a basin-wide basis. It is anticipated that continuing developments in the magnetic method will further increase its diagnostic capability, while at the same time reduce the unit cost of the information gained.
Another common property of iron is its generally high density. It is no surprise that the gravity method ranks immediately behind the magnetic method as the most efficacious exploration tool for iron. While porosities, and therefore densities of iron ore, have a wide range, the gravity method is nonetheless widely deployed in the search for iron. Gravity methods have seen similar advances in capability to that of the magnetic method, though in a much shorter time frame. This has culminated in the recent development of airborne gravity gradiometry, reducing the time required and the cost of data acquisition while spectacularly increasing survey coverage. As with the magnetic method, further developments in airborne gravity gradiometry will see the acquisition cost continue to decrease, allowing the method to be applied more often.
Other methods, such as radiometric, electrical, multispectral scanning (MSS), and seismic, have niche but important applications. While radiometric and MSS methods are restricted to the surface chemistries of the earth, they have important applications as geologic mapping methods. Though not peculiar to iron exploration, there are iron mineral assemblages and geologic processes that make the methods amenable for that purpose. Similarly, electrical methods, though marginal in iron ore detection, are being used increasingly to aid in geologic mapping and decrease interpretation ambiguity.
The same evolution that has seen vast increases in data collection capabilities has also fed numeric modeling and data transformation advances. Automated modeling schemes that can incorporate a priori information are now the norm. Explosive increases in computing capacity have seen rapid development of multiparameter inversion modeling using multiple geophysical data sets. The aim is no longer fitting a field curve with a single body solution, but developing a "whole of earth" model showing all elements of the detected geology.
It is anticipated that future advances in geophysics will be heavily biased to data collection techniques and further reduction of acquisition costs. This will obviate the need to decide on which geophysical survey to run—multimethod platforms will deliver multiple datasets at high data density and low cost. Although it is unlikely any new techniques will evolve, some methods may see the transition from the lab bench to the field as technology further improves.