Redistribution of soil mercury species mediated by thiolated biochar under dry–wet cycles

Zongwu Wang; Leiyi Zhang; Hao Hu; Jianyi He; Zehang Liang; Yao Huang

doi:10.1007/s42773-026-00608-w

Biochar ›› 2026, Vol. 8 ›› Issue (1) :90 DOI: 10.1007/s42773-026-00608-w

Original Research

research-article

Redistribution of soil mercury species mediated by thiolated biochar under dry–wet cycles

Author information +

History +

PDF

Abstract

Frequent heatwave events increase the frequency of soil dry–wet cycles, accelerating soil weathering and indirectly triggering mercury (Hg) activation risks. Thiol-modified biochar (TMB) has been widely demonstrated as an effective environmental material for immobilizing soil Hg. However, whether TMB can maintain long-term stability under frequent dry–wet conditions, and how it regulates key soil components to influence Hg behavior, remain unknown. In this study, 30 cycles of simulated dry–wet alternation confirm that TMB promotes soil mineral weathering to redistribute Hg species, thereby reducing total Hg leaching under acid rain, lowering Hg bioavailability, and decreasing net methylmercury accumulation. Specifically: (i) TMB accelerates the dissolution of soil calcium carbonate (CaCO₃) by 19.1%, reducing the total proportion of exchangeable and carbonate-bound Hg by 89.7%, while increasing soil pH by 8.5% and decreasing zeta potential by 1.7-fold, which favors Hg precipitation and electrostatic adsorption by soil particles; (ii) TMB facilitates the transformation of Fe/Al oxides (e.g., Fe₂O₃, Al₂O₃) into hydroxylated forms with stronger binding capacity (e.g., FeO·OH, Al(OH)₃), leading to decreased residual-bound Hg and increased oxide-bound Hg; (iii) TMB enhances the release of soil organic matter (e.g., mineral-associated), which improves Hg complexation capacity and reduces its availability, thereby lowering net methylmercury accumulation. Additionally, TMB increases the relative abundances of Bacillales, Gemmatimonadales, and other taxa in soil microbial community, and enhances the species richness and evenness. This study highlights the critical role of TMB-mediated mineral weathering in promoting Hg redistribution, elucidates the intrinsic mechanism underlying long-term Hg immobilization by TMB under heatwave-accelerated dry–wet conditions, and provides a theoretical basis for the sustainable engineering application of TMB in Hg-contaminated soil remediation.

Graphical Abstract

Keywords

Thiol-modified biochar / Heatwave / Dry–wet cycles / Mercury species / Soil

Cite this article

Download citation ▾

Zongwu Wang, Leiyi Zhang, Hao Hu, Jianyi He, Zehang Liang, Yao Huang. Redistribution of soil mercury species mediated by thiolated biochar under dry–wet cycles. Biochar, 2026, 8(1): 90 DOI:10.1007/s42773-026-00608-w

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Breemen NV, Mulder J, Driscoll CT. Acidification and alkalinization of soils. Plant Soil, 1983, 75: 283-308

[2]	Chen L, Liang S, Liu M, Yi Y, Mi Z, Zhang Y, Li Y, Qi J, Meng J, Tang X, Zhang T, Y. H, Zhang W, Wang X, Shu J, Yang Z. Trans-provincial health impacts of atmospheric mercury emissions in China. Nat Commun, 2019, 10 1484

[3]	Cheng P, Li Z, Zheng Y, Meng Q, Yu Y, Jin Y, Gao X, Guo X, Jia L. Study on the regulation of performance and Hg0 removal mechanism of MIL-101(Fe)-derived carbon materials. Sep Purif Technol, 2025, 379 134939

[4]	Conrad SR, Santos IR, White SA, Hessey S, Sanders CJ. Elevated dissolved heavy metal discharge following rainfall downstream of intensive horticulture. Appl Geochem, 2020, 113 104490

[5]	Dixon JL, Chadwick OA, Vitousek PM. Climate‐driven thresholds for chemical weathering in postglacial soils of New Zealand. J Geophys Res Earth Surf, 2016, 121: 1619-1634

[6]	Dzombak RM, Sheldon ND. Weathering intensity and presence of vegetation are key controls on soil phosphorus concentrations: implications for past and future terrestrial ecosystems. Soil Syst, 2020, 4 73

[7]	Fitzpatrick RW, Schwertmann U. Al-substituted goethite-an indicator of pedogenic and other weathering environments in South Africa. Geoderma, 1982, 27: 335-347

[8]	He G, Zhang Z, Wu X, Cui M, Zhang J, Huang X. Adsorption of heavy metals on soil collected from lixisol of typical karst areas in the presence of CaCO₃ and soil clay and their competition behavior. Sustainability Basel, 2020, 12: 7315

[9]	He J, Huang Y, Mo R, Liang Z, Liang Y, Cui J, Xiao Y. Defect-driven electron transfer for arsenic detoxification in iron-carbon materials. Environ Res, 2026, 294 123789

[10]	Huang Y, Wang M, Li Z, Gong Y, Zeng E. In situ remediation of mercury-contaminated soil using thiol-functionalized graphene oxide/Fe-Mn composite. J Hazard Mater, 2019, 373: 783-790

[11]	Huang Y, Xia S, Lyu J, Tang J. Highly efficient removal of aqueous Hg²⁺ and CH₃Hg⁺ by selective modification of biochar with 3-mercaptopropyltrimethoxysilane. Chem Eng J, 2019, 360: 1646-1655

[12]	Huang Y, Huang Y, Fang L, Zhao B, Zhang Y, Zhu Y, Wang Z, Wang Q, Li F. Interfacial chemistry of mercury on thiol-modified biochar and its implication for adsorbent engineering. Chem Eng J, 2023, 454 140310

[13]	Huang Y, Zhao B, Liu G, Liu K, Dang B, Lyu H, Tang J. Effective reducing the mobility and health risk of mercury in soil under thiol-modified biochar amendment. J Hazard Mater, 2024, 462 132712

[14]	Huang Y, Huang Y, Reinfelder JR, Zhong H, Fang L, Liu C, Li F. Phenol-quinone redox couples of natural organic matter promote mercury methylation in paddy soil. Environ Sci Technol, 2025, 59: 1179-1188

[15]	Jackson ML, Sherman GD. Chemical weathering of minerals in soils. Adv Agron, 1953, 5: 219-318

[16]	Lehmann J, Rillig MC, Thies J, Masiello CA, Hockaday WC, Crowley D. Biochar effects on soil biota—a review. Soil Biol Biochem, 2011, 43: 1812-1836

[17]	Li W, Deng Y, Wang H, Hu Y, Cheng H. Potential risk, leaching behavior and mechanism of heavy metals from mine tailings under acid rain. Chemosphere, 2024, 350 140995

[18]	Li J, Wang S, Zhu J, Wang D, Zhao T. Accelerated shifts from heatwaves to heavy rainfall in a changing climate. Npj Clim Atmos Sci, 2025, 8 214

[19]	Lindroos A, Brügger T, Derome J, Derome K. The weathering of mineral soil by natural soil solutions. Water Air Soil Pollut, 2003, 149: 269-279

[20]	Liu M, Zhu J, Yang X, Fu Q, Hu H, Huang Q. Mineralization of organic matter during the immobilization of heavy metals in polluted soil treated with minerals. Chemosphere, 2022, 301 134794

[21]	Liu S, Cen B, Yu Z, Qiu R, Gao T, Long X. The key role of biochar in amending acidic soil: reducing soil acidity and improving soil acid buffering capacity. Biochar, 2025, 7 52

[22]	Maraun D, Schiemann R, Ossó A, Jury M. Changes in event soil moisture-temperature coupling can intensify very extreme heat beyond expectations. Nat Commun, 2025, 16 734

[23]	Martinez-Villalobos C, Fu D, Loikith PC, Neelin JD. Accelerating increase in the duration of heatwaves under global warming. Nat Geosci, 2025, 18: 716-723

[24]	Meite F, Alvarez-Zaldívar P, Crochet A, Wiegert C, Payraudeau S, Imfeld G. Impact of rainfall patterns and frequency on the export of pesticides and heavy-metals from agricultural soils. Sci Total Environ, 2018, 616–617: 500-509

[25]	Oludare FV. Effects of weathering and erosion on the geochemistry of rocks and soils. Int J Sci Res Sci Technol, 2017, 3: 74-80

[26]	Park J, Lee D, Kim H, Woo NC. Effects of dry and heavy rainfall periods on arsenic species and behaviour in the aquatic environment adjacent a mining area in South Korea. J Hazard Mater, 2023, 441 129968

[27]	Qiao P, Wang S, Li J, Zhao Q, Wei Y, Lei M, Yang J, Zhang Z. Process, influencing factors, and simulation of the lateral transport of heavy metals in surface runoff in a mining area driven by rainfall: a review. Sci Total Environ, 2023, 857 159119

[28]	Raulund-Rasmussen K, Borggaard OK, Hansen HCB, Olsson M. Effect of natural organic soil solutes on weathering rates of soil minerals. Eur J Soil Sci, 1998, 49: 397-406

[29]	Sánchez-Marañón M, Molinero-García A, Delgado R, García del Moral LF, Martín-García JM. Spectral analysis of Fe oxidation in the early stages of weathering and soil formation. CATENA, 2023, 222 106850

[30]	Shao J, Ma H, Song Y, Chen H. Roles of soil moisture-air temperature coupling in three types of heatwaves over the Greater Bay Area of China. J Meteorol Res, 2025, 39: 959-973

[31]	Smeck NE. Phosphorus: an indicator of pedogenetic weathering processes. Soil Sci, 1973, 115: 199-206

[32]	Sun Y, Zhang D, Li F, Tao H, Li M, Mao L, Gu Z, Ling Z, Shi H. The rainfall effect onto solidification and stabilization of heavy metal-polluted sediments. R Soc Open Sci, 2020, 7 192234

[33]	Tessier A, Campbell PGC, Bisson M. Sequential extraction procedure for the speciation of particulate trace metals. Anal Chem, 1979, 51: 844-851

[34]	Wang F, Li W, Wang H, Hu Y, Cheng H. The leaching behavior of heavy metal from contaminated mining soil: the effect of rainfall conditions and the impact on surrounding agricultural lands. Sci Total Environ, 2024, 914 169877

[35]	Wang Z, Jia J, Liu W, Huang S, Chen X, Zhang N, Huang Y. Mercury speciation transformation mediated by thiolated biochar in high salinity groundwater: interfacial processes, influencing factors, and mechanisms. Chem Eng J, 2024, 484 149443

[36]	Watanabe T, Funakawa S, Kosaki T. Clay mineralogy and its relationship to soil solution composition in soils from different weathering environments of humid Asia: Japan, Thailand and Indonesia. Geoderma, 2006, 136: 51-63

[37]	Wolthers M. How minerals dissolve. Science, 2015, 349: 1288

[38]	Xing Y, Wang J, Shaheen SM, Feng X, Chen Z, Zhang H, Rinklebe J. Mitigation of mercury accumulation in rice using rice hull-derived biochar as soil amendment: a field investigation. J Hazard Mater, 2020, 388 121747

[39]	Zhang P, Fan J, Xu X, Xu Z, Yu Y, Zhao L, Qiu H, Cao X. Contrasting effects of dry-wet and freeze-thaw aging on the immobilization of As in As-contaminated soils amended by zero-valent iron-embedded biochar. J Hazard Mater, 2022, 426 128123

[40]	Zhang L, Wang B, Wu W, Wang C, Cheng H, Duan X. Enhanced health risk of soil heavy metal exposure following an extreme rainstorm under climate change. Sci Total Environ, 2024, 954 176409

[41]	Zhang K, Zuo Z, Mei W, Zhang R, Dai A. A westward shift of heatwave hotspots caused by warming-enhanced land-air coupling. Nat Clim Chang, 2025, 15: 546-553

[42]	Zhao B, O’Connor D, Shen Z, Tsang DCW, Rinklebe J, Hou D. Sulfur-modified biochar as a soil amendment to stabilize mercury pollution: an accelerated simulation of long-term aging effects. Environ Pollut, 2020, 264 114687

[43]	Zheng Y, Cheng P, Li Z, Fan C, Wen J, Yu Y, Jia L. Efficient removal of gaseous elemental mercury by Fe-UiO-66@BC composite adsorbent: performance evaluation and mechanistic elucidation. Sep Purif Technol, 2025, 372 133463

[44]	Zhou J, Liu Z, Li Z, Xie R, Jiang X, Cheng J, Chen T, Yang X. Heavy metals release in lead-zinc tailings: effects of weathering and acid rain. J Hazard Mater, 2025, 483 136645