Characteristics and genesis of hematite in Chinese loess and paleosol sequences： Mineral genetic restriction for magnetic susceptibility as paleoclimate proxy and iron geochemistry

Hematite is an important iron oxide mineral in loess-paleosol sequences in central China. Investigation of the mineralogical characteristics, genetic mechanism and relationship of hematite with other iron oxides and Fe-bearing minerals will help understand the geochemical process before and after eolian deposit, paleocliamte significance of magnetic susceptibility and reconstruct paleoclimate in central China. So, hematite and related minerals of the loess and paleosol units from Chinese Loess Plateau were investigated using optical microscope, X-ray powder diffraction （XRD）, scanning electron microscopy （SEM）, and high-resolution transmission microscopy （HRTEM）. The results show that there are five genetic types of hematite in loess-paleosol sequences of central China： （1） weathering of Fe-bearing silicate minerals, for instance, chlorite, will release iron that is precipitated as aggregates of hematite nano-crystals on mineral surfaces; （2） hematite combined with eolian magnetite grains that resulted from partial oxidation of magnetite, even though the partial oxidation may occur in the original area; （3） phase transformation from eolian goethite to hematite; （4） hematite formed on the edge and surface of maghemite because of dissolution and hematite recrystallization; and （5） eolian detrial hematite. The hematite formed from chemical weathering of Fe-bearing silicates with nanoporous texture because of dehydration from iron hydroxide is the most important genetic mechanism. It is proposed that the fact that hematite was formed from chemical weathering of Fe-bearing silicates is a main reason for the redness in paleosol units. However, too intense pedogenesis and high amounts of precipitation will promote oxidation of eolian magnetite and maghemite dissolution, which may result in the decreasing of magnetic susceptibility.