Response of dissolved organic carbon molecular footprints in mangrove tidal flats to extreme rainstorm events

Licong Zhang; Kai Xiao; Peng Zhang; Kai Wang; Ding He; Guangxuan Han; Chunmiao Zheng

doi:10.20517/cf.2025.63

Carbon Footprints ›› 2025, Vol. 4 ›› Issue (4) :34 DOI: 10.20517/cf.2025.63

Original Article

Response of dissolved organic carbon molecular footprints in mangrove tidal flats to extreme rainstorm events

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Abstract

Mangroves, as typical blue carbon ecosystems, store massive amounts of soil organic carbon and serve as both sources and sinks of organic carbon. Under extreme rainstorm conditions, once mangrove ecosystems are damaged, they lead to significant release of greenhouse gases into the atmosphere, causing severe greenhouse effects and resulting in changes to carbon footprints. However, the effects of extreme rainstorms on the spatial distribution, optical properties, and molecular characteristics of soil organic carbon in mangrove sediments remain unclear. This study focused on a typical mangrove tidal flat in Shenzhen Bay, Southeast China, to quantify variations in sediment carbon fractions (total carbon (TC), dissolved organic carbon (DOC), and dissolved inorganic carbon (DIC)), fluorescent composition, and biomolecular compounds of DOC, and identified their response mechanisms to extreme rainstorms. The results showed that the spatial distribution of sediment TC, DOC, and total nitrogen (TN) followed the order of tidal creek > mudflat > mangrove both before and after a rainstorm. The variation degree of DOC content (5.0%-48.5%) after extreme rainstorms followed the pattern of mangrove > mudflat > creek, while the result for DIC was completely opposite. In the vertical direction, tidal flat sediments exhibited decreasing TC, DOC, and TN concentrations with depth before the extreme rainstorm. After the rainstorm, DOC and TN increased across all sediment layers, whereas IC decreased at all depths. After the extreme rainstorm, TN and DOC in sediments increased significantly. Combined with analysis of the optical and molecular properties of DOC, the results indicated that lignin- and tannin-like compounds with high stability increased in mudflat sediments after the extreme rainstorm, while tryptophan-like compounds with high aromaticity and low humification increased in mangrove sediments, and protein-like organic compounds in tidal creek sediments decreased. Principal component analysis showed that extreme rainstorms mainly affected sediment DOC by influencing the transport of silt and clay. This study not only contributes to a better understanding of how extreme rainstorms regulate organic carbon behavior in mangrove sediments to improve sustainable management of mangrove wetlands under the pressure of extreme weather events but also provides new directions for carbon footprint research.

Keywords

Extreme rainstorm / dissolved organic carbon / fluorescent composition / tidal flat / Shenzhen Bay

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Licong Zhang, Kai Xiao, Peng Zhang, Kai Wang, Ding He, Guangxuan Han, Chunmiao Zheng. Response of dissolved organic carbon molecular footprints in mangrove tidal flats to extreme rainstorm events. Carbon Footprints, 2025, 4(4): 34 DOI:10.20517/cf.2025.63

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References

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

[1]	Lu Y,Lu X.Major threats of pollution and climate change to global coastal ecosystems and enhanced management for sustainability.Environ Pollut2018;239:670-80

[2]	Murray NJ,Bunting P.High-resolution mapping of losses and gains of Earth's tidal wetlands.Science2022;376:744-9

[3]	D'sa EJ,Liu B.Extreme events and impacts on organic carbon cycles from ocean color remote sensing: review with case study, challenges, and future directions.Earth-Sci Rev2023;243:104503

[4]	Choudhary B,Pawase AS.Blue carbon and the role of mangroves in carbon sequestration: its mechanisms, estimation, human impacts and conservation strategies for economic incentives.J Sea Res2024;199:102504

[5]	Wang M,Xie Y,Wu X.Mapping accumulated carbon storage of global mangroves from 2000 to 2020 at a 1 km resolution.Sci Data2025;12:552 PMCID:PMC11961717

[6]	Alongi DM.Carbon cycling and storage in mangrove forests.Ann Rev Mar Sci2014;6:195-219

[7]	Bandh SA,Qayoom I.Importance of blue carbon in mitigating climate change and plastic/microplastic pollution and promoting circular economy.Sustainability2023;15:2682

[8]	Weiskopf SR,Crozier LG.Climate change effects on biodiversity, ecosystems, ecosystem services, and natural resource management in the United States.Sci Total Environ2020;733:137782

[9]	Hawkes JA,Moodie LWK.Enhanced structural understanding of dissolved organic matter through comparative LC/MS2 analysis with synthetic carboxylate rich alicyclic molecules.Anal Chem2025;97:18612-20 PMCID:PMC12409697

[10]	Pradisty NA,Zimmer M.Plant species- and stage-specific differences in microbial decay of mangrove leaf litter: the older the better?.Oecologia2021;195:843-58

[11]	Liu T,Chen M,Gao C.Human activity has increasingly affected recent carbon accumulation in Zhanjiang mangrove wetland, South China.iScience2024;27:109038 PMCID:PMC10867414

[12]	Wang Z,Kang W,Feng R.Interactions between dissolved organic matter and the microbial community are modified by microplastics and heat waves.J Hazard Mater2023;448:130868

[13]	Gao H.Heterogeneity in composition and reactivity of dissolved organic matter and metal partitioning in soil. Wageningen University; 2025.

[14]	Jian Z,Huang X,Hu Q.Optical absorption characteristics, spatial distribution, and source analysis of colored dissolved organic matter in wetland water around Poyang lake.Water2021;13:274

[15]	Alongi DM.Lateral export and sources of subsurface dissolved carbon and alkalinity in mangroves: revising the blue carbon budget.J Mar Sci Eng2022;10:1916

[16]	Herzsprung P,Wilske C.Data evaluation strategy for identification of key molecular formulas in dissolved organic matter as proxies for biogeochemical reactivity based on abundance differences from ultrahigh resolution mass spectrometry.Water Res2023;232:119672

[17]	Merder J,Feudel U,Singer G.Improved mass accuracy and isotope confirmation through alignment of ultrahigh-resolution mass spectra of complex natural mixtures.Anal Chem2020;92:2558-65

[18]	Weishaar JL,Bergamaschi BA,Fujii R.Evaluation of specific ultraviolet absorbance as an indicator of the chemical composition and reactivity of dissolved organic carbon.Environ Sci Technol2003;37:4702-8

[19]	Murphy KR,Graeber D.Fluorescence spectroscopy and multi-way techniques. PARAFAC.Anal Methods2013;5:6557-66

[20]	Darby SE,Leyland J.Fluvial sediment supply to a mega-delta reduced by shifting tropical-cyclone activity.Nature2016;539:276-9

[21]	Scavia D,Boesch DF.Climate change impacts on U.S. Coastal and Marine Ecosystems.Estuaries2002;25:149-64

[22]	Griffiths LN.Estimating the effects of a hurricane on carbon storage in mangrove wetlands in Southwest Florida.Plants2021;10:1749 PMCID:PMC8398776

[23]	Jonsson S,Nilsson MB.Terrestrial discharges mediate trophic shifts and enhance methylmercury accumulation in estuarine biota.Sci Adv2017;3:e1601239 PMCID:PMC5271591

[24]	Alongi DM.Current status and emerging perspectives of coastal blue carbon ecosystems.Carbon Footprints2023;2:12

[25]	Cao F.Impacts of hydrology and extreme events on dissolved organic carbon dynamics in a heavily urbanized estuary and its major tributaries: a view from space.JGR Biogeosci2024;129:e2023JG007767

[26]	Zeng J,Jian Z,Zhao J.Analysis of mangrove dynamics and its protection effect in the Guangdong-Hong Kong-Macao Coastal Area based on the Google Earth Engine platform.Front Mar Sci2023;10:1170587

[27]	Zhang YH.Background values of pollutants in sediments of the South China Sea.Acta Oceanol Sin2015;4:161-6. (in Chinese)Available from: http://hyxbocean.cn/en/article/id/20050422 [Last accessed on 14 Nov 2025]

[28]

Tang TJ,Peng Y.Pollution and prevention countermeasure for water environment of Shenzhen bay.Environ Sci Manag2016;41:43-55. (in Chinese)Available from: https://kns.cnki.net/kcms2/article/abstract?v=sTAINAsmd8_rYc71em4TvC-qmWoo-OFwGF8--u-2es5QFJ_3V6fiAYBEW_bPV3Vz59Zfm0HL3v3I7joDi85lr2JKnm52Ub5HiCP4R7t_qG9M2u62FC9pmv0KkYnWmw1aEElSZ92hWWHwSGrm1LsqtDZgd4iqYCKTs_lY_9Qk04uymne5d1tQiA==&uniplatform=NZKPT&language=CHS [Last accessed on 14 Nov 2025]

[29]	Li W,Liu Y.Current status and prospect of water environment management in Shenzhen Bay.China Water Wastewater2016;32:29-41. (in Chinese)

[30]	Stedmon CA.Characterizing dissolved organic matter fluorescence with parallel factor analysis: a tutorial.Limnol Ocean Methods2008;6:572-9

[31]	Helms JR,Ritchie JD,Kieber DJ.Absorption spectral slopes and slope ratios as indicators of molecular weight, source, and photobleaching of chromophoric dissolved organic matter.Limnol Oceanogr2008;53:955-69

[32]	Cory RM.Fluorescence spectroscopy reveals ubiquitous presence of oxidized and reduced quinones in dissolved organic matter.Environ Sci Technol2005;39:8142-9

[33]	Ohno T.Fluorescence inner-filtering correction for determining the humification index of dissolved organic matter.Environ Sci Technol2002;36:742-6

[34]	Wilson HF.Effects of agricultural land use on the composition of fluvial dissolved organic matter.Nat Geosci2009;2:37-41

[35]	Dittmar T,Hertkorn N.A simple and efficient method for the solid-phase extraction of dissolved organic matter (SPE-DOM) from seawater.Limnol Ocean Methods2008;6:230-5

[36]	Wang K,Yi Y.Response of dissolved organic matter chemistry to flood control of a large river reservoir during an extreme storm event.Water Res2023;230:119565

[37]	D'Andrilli J,Foreman CM.An ultrahigh-resolution mass spectrometry index to estimate natural organic matter lability.Rapid Commun Mass Spectrom2015;29:2385-401 PMCID:PMC4654268

[38]	Zhang J.Risk assessment of flood disaster induced by typhoon rainstorms in Guangdong Province, China.Sustainability2019;11:2738

[39]	Shutova Y,Bridgeman J.Spectroscopic characterisation of dissolved organic matter changes in drinking water treatment: from PARAFAC analysis to online monitoring wavelengths.Water Res2014;54:159-69

[40]	Tomco PL,Miller LC,Campbell RW.DOC export is exceeded by C fixation in May Creek: a late-successional watershed of the Copper River Basin, Alaska.PLoS One2019;14:e0225271 PMCID:PMC6867643

[41]	Lin H.Variations in colloidal DOM composition with molecular weight within individual water samples as characterized by flow field-flow fractionation and EEM-PARAFAC analysis.Environ Sci Technol2020;54:1657-67

[42]	Yamashita Y,Kawai K,Fujita H.The role of the isolation of the marginal seas during the Pleistocene in the genetic structure of black sea bream Acanthopagrus schlegelii (Bleeker, 1854) in the coastal waters of Japan.PeerJ2021;9:e11001 PMCID:PMC8020869

[43]	Matos CR,Machado W.Seasonal changes in metal and nutrient fluxes across the sediment-water interface in tropical mangrove creeks in the Amazon region.Appl Geochem2022;138:105217

[44]	Taillardat P,Friess DA.Assessing nutrient dynamics in mangrove porewater and adjacent tidal creek using nitrate dual-stable isotopes: a new approach to challenge the Outwelling Hypothesis?.Mar Chem2019;214:103662

[45]	Adame MF,Lovelock CE.Effect of geomorphological setting and rainfall on nutrient exchange in mangroves during tidal inundation.Mar Freshwater Res2010;61:1197-206

[46]	Davis SE,Childers DL.Temporally dependent C, N, and P dynamics associated with the decay of Rhizophora mangle L. leaf litter in oligotrophic mangrove wetlands of the Southern Everglades.Aquatic Botany2003;75:199-215

[47]	Romero LM,Fourqurean JW.Changes in mass and nutrient content of wood during decomposition in a south Florida mangrove forest.J Ecol2005;93:618-31

[48]	Tan LS,Li SH.Impacts of land-use change on carbon dynamics in China's coastal wetlands.Sci Total Environ2023;890:164206

[49]	Kaiser K.The role of DOM sorption to mineral surfaces in the preservation of organic matter in soils.Org Geochem2000;31:711-25

[50]	Lalonde K,Ouellet A.Preservation of organic matter in sediments promoted by iron.Nature2012;483:198-200

[51]	Riedel T,Biester H.Iron traps terrestrially derived dissolved organic matter at redox interfaces.Proc Natl Acad Sci USA2013;110:10101-5 PMCID:PMC3690857

[52]	Jiao N,Hansell DA.Microbial production of recalcitrant dissolved organic matter: long-term carbon storage in the global ocean.Nat Rev Microbiol2010;8:593-9

[53]	Wang H,Chen G.The loss of dissolved organic matter from biological soil crust at various successional stages under rainfall of different intensities: Insights into the changes of molecular components at different rainfall stages.Water Res2024;257:121719

[54]	Eckard RS,Bergamaschi BA.Dissolved organic matter compositional change and biolability during two storm runoff events in a small agricultural watershed.JGR Biogeosci2017;122:2634-50

[55]	Kleber M,Keiluweit M,Mikutta R.Chapter One - Mineral-organic associations: formation, properties, and relevance in soil environments. In Advances in agronomy. Academic Press; 2015; pp. 1-140.