Facies-dependent compositional variation in K-bentonites from lagoonal to littoral environments (Permian-Triassic transition, southwestern China)

Xiaoxue JIN; Thomas J. ALGEO; Chen LIU; Hanlie HONG

doi:10.1007/s11707-025-1164-z

Front. Earth Sci. ›› 2025, Vol. 19 ›› Issue (4) :550 -565. DOI: 10.1007/s11707-025-1164-z

RESEARCH ARTICLE

Facies-dependent compositional variation in K-bentonites from lagoonal to littoral environments (Permian-Triassic transition, southwestern China)

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Abstract

The alteration pathways of volcanic ashes depend on the physicochemical conditions of the watermass in which they are deposited. Different conditions in terrestrial, paralic, and marine facies may impart recognizable chemical signatures on altered ash beds (i.e., K-bentonites) that are potentially useful for distinguishing depositional facies in ancient ash-bearing stratigraphic successions. Western Guizhou Province in South China contains widespread Permian-Triassic transition strata from terrestrial lacustrine to shallow-marine shelf facies. In this study, factors influencing the mineralogy and geochemistry of K-bentonites accumulating across a spectrum of freshwater facies in Permian-Triassic transition strata of south-western China were comparatively investigated using mineralogical and geochemical data. Our results show that K-bentonites preserve diagnostic information regarding their depositional environment. The clay mineral assemblages of these K-bentonites are facies-dependent, with dominance of mixed-layer illite/smectite (I/S) clays in freshwater lacustrine facies, kaolinite and I/S in lagoonal facies, mixed-layer kaolinite/smectite (K/S) in mixed marine-terrestrial facies, and smectite and I/S in littoral-neritic facies. The lagoonal Chinahe (CNH) K-bentonites exhibit clay mineral compositions dominated by kaolinite (both highly and poorly crystalline forms) and R1 and R3 I/S clays; the CNH-16 K-bentonite additionally contains minor chlorite. The abundance of kaolinite and absence of smectite in the CNH K-bentonites resulted from strong chemical weathering in an organic acid-rich and oxidizing environment characterized by low porewater pH. The littoral Langdai (LD) K-bentonites contain mainly R1 and R3 mixed-layer illite/smectite (I/S) and smectite, with minor poorly crystalline kaolinite, suggesting a higher pH in seawater-derived pore fluids. The littoral LD K-bentonites and their host sediments have Sr/Ba ratios of 0.34−0.49, consistent with deposition in brackish coastal facies, whereas the higher Sr/Ba ratios of the CNH K-bentonites (0.67−1.07) indicate deposition in a marine to slightly hypersaline lagoonal facies linked to warm, arid climate conditions.

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K-bentonites / mixed-layer illite/smectite (I/S) / salinity / porewater pH / sedimentary environment / anatase

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Xiaoxue JIN, Thomas J. ALGEO, Chen LIU, Hanlie HONG. Facies-dependent compositional variation in K-bentonites from lagoonal to littoral environments (Permian-Triassic transition, southwestern China). Front. Earth Sci., 2025, 19(4): 550-565 DOI:10.1007/s11707-025-1164-z

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