Environmental magnetism linked to weathering processes: A study on surface soils from an East Antarctic oasis

• Published in: Geoderma Regional Vol. 41; p. e00954
• Main Authors: Rath, Adyasha, Joju, G.S., Warrier, Anish Kumar, Chaparro, Marcos A.E., Badesab, Firoz, Venkateshwarlu, Mamilla, Mahesh, B.S., Mohan, Rahul
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.06.2025
• Subjects: Antarctic region; Antarctica; Environmental magnetism; Gelisols; hematite; hysteresis; iron oxides; magnetic susceptibility; magnetism; Magnetite; oases; Pedogenesis; Schirmacher oasis; soil; Weathering; Antarctica; Antarctic region; Pedogenesis; Environmental magnetism; Schirmacher oasis; Magnetite; iron oxides; Weathering; Gelisols
• ISSN: 2352-0094; 2352-0094
• DOI: 10.1016/j.geodrs.2025.e00954

We determined and discussed the mineral magnetic properties of the soil samples (n = 78) from the Schirmacher Oasis, East Antarctica. Environmental magnetism analysis was conducted to identify the mechanisms controlling the formation and distribution of iron oxide minerals such as magnetite and hematite. Magnetic susceptibility (χlf) exhibited a mean (± SD) value of 109.5 (± 76.6) × 10−8 m3kg−1, indicating the presence of magnetically strong minerals. A statistically significant correlation (r = 0.79; p < 0.01) between χlf and saturation isothermal remanent magnetization (SIRM), the S-ratio values (0.97–0.99) and temperature-dependent magnetization measurements, suggests that low-coercivity magnetic minerals, such as magnetite, primarily regulate the magnetic signal. The percentage of frequency-dependent susceptibility remains below 2 % for most samples, indicating an insignificant presence of ultrafine superparamagnetic grains. The χARM/SIRM parameter (mean (± SD) values of 53.7 (± 26.3) × 10−5 mA−1) suggests a predominance of coarse-grained magnetic minerals, while magnetic hysteresis parameters indicate the dominance of multidomain magnetic grains, with minor proportions of single-domain and superparamagnetic grains. Various inter-parametric ratios reveal the absence of bacterial magnetite, anthropogenic magnetite, and authigenic greigite, suggesting that the magnetic minerals in these Antarctic soils from Schirmacher Oasis predominantly result from weathering processes.