Phosphorus/iron-doped biochar enabling a synergy for cadmium immobilization and carbon sequestration in fluctuating redox paddy soils

Hao Shi , Yixin Chen , Yiquan Xing , Jingwei Zhang , Wenhao Dong , Murray B. McBride , Zhaojie Cui , Lei Wang , Xinxin Li

Biochar ›› 2025, Vol. 7 ›› Issue (1)

PDF
Biochar ›› 2025, Vol. 7 ›› Issue (1) DOI: 10.1007/s42773-025-00481-z
Original Research
research-article

Phosphorus/iron-doped biochar enabling a synergy for cadmium immobilization and carbon sequestration in fluctuating redox paddy soils

Author information +
History +
PDF

Abstract

Biochar addition to soils is a promising strategy for mitigating cadmium (Cd) mobilization and carbon emission, but how biochar-to-soil interaction enabling a synergy between these two goals at redox heterointerface remains unclear. Herein, we conducted three types of paddy soil incubations with phosphorus/iron-doped biochar to explore the underlying factors and processes controlling Cd and carbon transformation under redox conditions. Upon flooding, lower soil redox potential resulted in soluble and extractable Cd transformed into Fe/Mn-bound fraction, coinciding with elevated CO2 and CH4 fluxes. During subsequent drainage, soil pH decrease caused associated Cd transformed back into exchangeable fraction, coupled with cumulative CO2 dropped. Both porewater and sequential extraction results revealed that the remobilization of Cd and carbon during redox fluctuations is largely related to Fe/Mn (hydr)oxide-induced effects. Microscopic and spectroscopic techniques determined that the organo-mineral (e.g., aliphatic C and Fe–O/Si–O groups) interactions are of crucial importance in influencing Cd and carbon distribution patterns on soil microaggregates. Further sequencing and correlation analyses vertified that this biochar facilitated simultaneous Cd and carbon retention via altering soil biogeochemistry, especially redox-controlled abiotic and microbial transformation processes. Overall, these findings shed light on the interactive effects of Cd and carbon mitigation with biochar amendment for redox paddy environments.

Keywords

Cadmium / Carbon / Biochar / To / Soil interactions / Biotic / Abiotic mechanisms / Flooding / Drainage alternation

Cite this article

Download citation ▾
Hao Shi, Yixin Chen, Yiquan Xing, Jingwei Zhang, Wenhao Dong, Murray B. McBride, Zhaojie Cui, Lei Wang, Xinxin Li. Phosphorus/iron-doped biochar enabling a synergy for cadmium immobilization and carbon sequestration in fluctuating redox paddy soils. Biochar, 2025, 7(1): DOI:10.1007/s42773-025-00481-z

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]

AdhikariD, YangY. Selective stabilization of aliphatic organic carbon by iron oxide. Sci Rep, 2015, 5111214
[2]

BussW, WurzerC, ManningDAC, et al.. Mineral-enriched biochar delivers enhanced nutrient recovery and carbon dioxide removal. Commun Earth Environ, 2022, 3167
[3]

ChenW, HabibulN, LiuX-Y, et al.. FTIR and synchronous fluorescence heterospectral two-dimensional correlation analyses on the binding characteristics of copper onto dissolved organic matter. Environ Sci TechNol, 2015, 49(4): 2052-2058
[4]

ChenN, FuQ, WuT, et al.. Active iron phases regulate the abiotic transformation of organic carbon during redox fluctuation cycles of paddy soil. Environ Sci Technol, 2021, 55(20): 14281-14293
[5]

ChenS, ChenL, WangD, et al.. Low pe+pH induces inhibition of cadmium sulfide precipitation by methanogenesis in paddy soil. J Hazard Mater, 2022, 437129297
[6]

ChenY, LiS, ChenX, et al.. Enhanced Cd activation by Coprinus comatus endophyte Bacillus thuringiensis and the molecular mechanism. Environ Pollut, 2024, 342130203
[7]

DaiG, LiX, FuH, et al.. A novel oxalated zero-valent iron nanoparticle for Pb(II) removal from aqueous solution: performance and stnergistic mechanisms. Sep Purif Technol, 2022, 302122017
[8]

DongY, SanfordRA, BoyanovMI, et al.. Controls on Iron reduction and biomineralization over broad environmental conditions as suggested by the Firmicutes Orenia metallireducens strain Z6. Environ Sci Technol, 2020, 54(16): 10128-10140
[9]

FangW, YangY, WangH, et al.. Rice rhizospheric effects on the bioavailability of toxic trace elements during land application of biochar. Environ Sci Technol, 2021, 55(11): 7344-7354
[10]

FuldaB, VoegelinA, KretzschmarR. Redox-controlled changes in cadmium solubility and solid-phase speciation in a paddy soil As affected by reducible sulfate and copper. Environ Sci Technol, 2013, 47(22): 12775-12783
[11]

GaoY, TongH, ZhaoZ, et al.. Effects of Fe oxides and their redox cycling on Cd activity in paddy soils: a review. J Hazard Mater, 2023, 456131665
[12]

HamidY, TangL, WangX, et al.. Immobilization of cadmium and lead in contaminated paddy field using inorganic and organic additives. Sci Rep, 2018, 8117839
[13]

HeH, LiuJ, ShuZ, et al.. Microbially driven iron cycling facilitates organic carbon accrual in decadal biochar-amended soil. Environ Sci Technol, 2024, 58(28): 12430-12440
[14]

Hernandez-SorianoMC, DalalRC, WarrenFJ, et al.. Soil organic carbon stabilization: mapping carbon speciation from intact microaggregates. Environ Sci Technol, 2018, 52(21): 12275-12284
[15]

HuD, ZengQ, ZhuJ, et al.. Promotion of humic acid transformation by abiotic and biotic Fe redox cycling in nontronite. Environ Sci Technol, 2023, 57(48): 19760-19771
[16]

HuP, ZhangY, WangJ, et al.. Mobilization of colloid- and nanoparticle-bound arsenic in contaminated paddy soils during reduction and reoxidation. Environ Sci Technol, 2023, 57(26): 9843-9853
[17]

HuangH, JiX-B, ChengL-Y, et al.. Free radicals produced from the oxidation of ferrous sulfides promote the remobilization of cadmium in paddy soils during drainage. Environ Sci Technol, 2021, 55(14): 9845-9853
[18]

HuangD, ChenN, ZhuC, et al.. Dynamic production of hydroxyl radicals during the flooding–drainage process of paddy soil: an in situ column study. Environ Sci Technol, 2023, 57(43): 16340-16347
[19]

KhanS, ChaoC, WaqasM, et al.. Sewage sludge biochar influence upon rice (Oryza sativa L.) yield, metal bioaccumulation and greenhouse gas emissions from acidic paddy soil. Environ Sci Technol, 2013, 47(15): 8624-8632
[20]

LiD, LaiC, LiY, et al.. Biochar improves cd-contaminated soil and lowers Cd accumulation in Chinese flowering cabbage (Brassica parachinensis L.). Soil till Res, 2021, 213105085
[21]

LiX, GrahamNJD, DengW, et al.. Structural variation of precipitates formed by Fe(II) oxidation and impact on the retention of phosphate. Environ Sci Technol, 2022, 56(7): 4345-4355
[22]

LiangG, StarkJ, WaringBG. Mineral reactivity determines root effects on soil organic carbon. Nat Commun, 2023, 1414962
[23]

LiuZ, ZhangW, MaR, et al.. Biochar–plant interactions enhance nonbiochar carbon sequestration in a rice paddy soil. Commun Earth Environ, 2023, 41494
[24]

LuoL, WangJ, LvJ, et al.. Carbon sequestration strategies in soil using biochar: advances, challenges, and opportunities. Environ Sci Technol, 2023, 57(31): 11357-11372
[25]

MinamikawaK, SakaiN. The practical use of water management based on soil redox potential for decreasing methane emission from a paddy field in Japan. Agr Ecosyst Environ, 2006, 116(3–4): 181-188
[26]

MohanD, AbhishekK, PatelM, et al.. Harnessing biochar in contaminated soil for heavy metal immobilization, soil health enhancement, and carbon sequestration. Ind Eng Chem Res, 2024, 63(23): 10380-10396
[27]

MueheEM, ObstM, HitchcockA, et al.. Fate of Cd during microbial Fe(III) mineral reduction by a novel and Cd-tolerant geobacter species. Environ Sci Technol, 2013, 47(24): 14099-14109
[28]

QuJ, LiY, BiF, et al.. Smooth vetch (Vicia villosa var.) coupled with ball-milled composite mineral derived from shell powder and phosphate rock for remediation of cadmium-polluted farmland: insights into synergetic mechanisms. ACS EST Eng, 2024, 4(8): 2054-2067
[29]

RibeiroDC, MartinsG, NogueiraR, et al.. Mineral cycling and pH gradient related with biological activity under transient anoxic–oxic conditions: effect on P mobility in volcanic lake sediments. Environ Sci Technol, 2014, 48(16): 9205-9210
[30]

SharmaN, WangZ, CatalanoJG, et al.. Dynamic responses of trace metal bioaccessibility to fluctuating redox conditions in wetland soils and stream sediments. ACS Earth Space Chem, 2022, 6(5): 1331-1344
[31]

SunF, PolizzottoML, GuanD, et al.. Exploring the interactions and binding sites between Cd and functional groups in soil using two-dimensional correlation spectroscopy and synchrotron radiation based spectromicroscopies. J Hazard Mater, 2017, 326: 18-25
[32]

SunF, YuG, HanX, et al.. Risk assessment and binding mechanisms of potentially toxic metals in sediments from different water levels in a coastal wetland. J Environ Sci, 2023, 129: 202-212
[33]

TumbureA, BishopP, BrethertonM, et al.. Co-pyrolysis of maize stover and igneous phosphate rock to produce potential biochar-based phosphate fertilizer with improved carbon retention and liming value. ACS Sustain Chem Eng, 2020, 8(10): 4178-4184
[34]

TuszynskaA, CzerwionkaK, Obarska-PempkowiakH. Phosphorus concentration and availability in raw organic waste and post fermentation products. J Environ Manag, 2021, 278111468
[35]

VoelzJL, JohnsonNW, ChunCL, et al.. Quantitative dissolution of environmentally accessible iron residing in iron-rich minerals: a review. ACS Earth Space Chem, 2019, 3(8): 1371-1392
[36]

WangJ, WangP-M, GuY, et al.. Iron–manganese (oxyhydro)oxides, rather than oxidation of sulfides, determine mobilization of cd during soil drainage in paddy soil systems. Environ Sci Technol, 2019, 53(5): 2500-2508
[37]

WangY, XiaoX, XuY, et al.. Environmental effects of silicon within biochar (sichar) and carbon–silicon coupling mechanisms: a critical review. Environ Sci Technol, 2019, 53(23): 13570-13582
[38]

WangL, ChenH, WuJ, et al.. Effects of magnetic biochar-microbe composite on Cd remediation and microbial responses in paddy soil. J Hazard Mater, 2021, 414125494
[39]

WuC, WangS, PengW, et al.. Fe(II)-catalyzed phase transformation of Cd(II)-bearing ferrihydrite-kaolinite associations under anoxic conditions: new insights to role of kaolinite and fate of Cd(II). J Hazard Mater, 2024, 468133798
[40]

YangY, YuanX, ChiW, et al.. Modelling evaluation of key cadmium transformation processes in acid paddy soil under alternating redox conditions. Chem Geol, 2021, 581120409
[41]

YangX, WenE, GeC, et al.. Iron-modified phosphorus- and silicon-based biochars exhibited various influences on arsenic, cadmium, and lead accumulation in rice and enzyme activities in a paddy soil. J Hazard Mater, 2023, 443130203
[42]

YinM, ZhangX, LiF, et al.. Multitask deep learning enabling a synergy for cadmium and methane mitigation with biochar amendments in paddy soils. Environ Sci Technol, 2023, 58(3): 1771-1782
[43]

YinY, WangY, DingC, et al.. Impact of iron and sulfur cycling on the bioavailability of cadmium and arsenic in co-contaminated paddy soil. J Hazard Mater, 2024, 465133798
[44]

YuW, ChuC, ChenB. Pyrogenic carbon improves Cd retention during microbial transformation of ferrihydrite under varying redox conditions. Environ Sci Technol, 2023, 57(20): 7875-7885
[45]

ZhaoM, LiuX, LiZ, et al.. Inhibition effect of sulfur on Cd activity in soil-rice system and its mechanism. J Hazard Mater, 2021, 407124647
[46]

ZhaoG, TanM, WuB, et al.. Redox oscillations activate thermodynamically stable iron minerals for enhanced reactive oxygen species production. Environ Sci Technol, 2023, 57(23): 8628-8637
[47]

ZhouG, ChenL, ZhangC, et al.. Bacteria–virus interactions are more crucial in soil organic carbon storage than iron protection in biochar-amended paddy soils. Environ Sci Technol, 2023, 57(48): 19713-19722

Funding

National Natural Science Foundation of China(52204187)

Natural Science Foundation of Shandong Province(ZR2022QD101)

RIGHTS & PERMISSIONS

The Author(s)

AI Summary AI Mindmap
PDF

115

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/