Mercury concentrations within Peruvian mangrove sediments

Wilson Machado; Breno Rodrigues; Victor de Freitas; Anderson Rocha; Christiane Duyck; Adan Lino; Olaf Malm; Christian J. Sanders; Matthieu Carré; Alexander Pérez

doi:10.1007/s44218-026-00127-y

Anthropocene Coasts ›› 2026, Vol. 9 ›› Issue (1) :8 DOI: 10.1007/s44218-026-00127-y

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Mercury concentrations within Peruvian mangrove sediments

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Abstract

The assessment of mercury (Hg) contamination in Peruvian mangrove sediments was conducted across two contrasting environments: the anthropogenically impacted mangrove forest of “Puerto Pizarro” (PP), affected by shrimp aquaculture, mining activities, and urban expansion, and the relatively pristine Mangrove Sanctuary of Tumbes (MS). In PP, Hg concentrations ranged from 291 to 177 ng g⁻¹, yielding a Pollution Index (PI) of 1.6 and exceeding the sediment quality guideline defined by the Effect Range Low (ERL; 150 ng g⁻¹), indicative of potential Hg toxicity. In contrast, Hg concentrations in MS ranged from 135 to 17 ng g⁻¹, remaining below the ERL and within natural background levels reported for Peruvian marine sediments. Using the estimated mean background concentration in MS sediments (70 ng g⁻¹), enrichment factors of up to 3.2 were observed in PP sediments. Mercury concentrations in MS exhibited significant positive correlations with fine-grained sediments (silt and clay; r=0.66) and reactive iron phases (r=0.70), reflecting natural geochemical controls on Hg accumulation. Conversely, no significant correlations were detected in PP, suggesting that anthropogenic inputs override sedimentological and geochemical processes. This study provides the first assessment of Hg concentrations in mangrove ecosystems located at the eastern South Pacific distributional limit and highlights the role of mangroves as effective biogeochemical barriers that mitigate Hg transfer to adjacent coastal ecosystems.

Keywords

Mercury contamination / Mangrove sediments / Anthropogenic impact / Enrichment factor / Biogeochemical barrier

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Wilson Machado, Breno Rodrigues, Victor de Freitas, Anderson Rocha, Christiane Duyck, Adan Lino, Olaf Malm, Christian J. Sanders, Matthieu Carré, Alexander Pérez. Mercury concentrations within Peruvian mangrove sediments. Anthropocene Coasts, 2026, 9(1): 8 DOI:10.1007/s44218-026-00127-y

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References

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

[1]	Abessa DMS, Albuquerque HC, Morais LG, Araújo GS, Fonseca TG, Cruz ACF, Campos BG, Camargo JBDA, Gusso-Choueri PK, Perina FC, Choueri RB, Buruaem LM. Pollution status of marine protected areas worldwide and the consequent toxic effects are unknown. Environ Pollut, 2018, 243: 1450-1459

[2]	Adamo P, Arienzo M, Imperato M, Naimo D, Nardi G, Stanzione D. Distribution and partition of heavy metals in surface and sub-surface sediments of Naples city port. Chemosphere, 2005, 61(6): 800-809

[3]

Alam MA, Gomes A, Sarkar SK, Shuvaeva OV, Vishnevetskaya NS, Gustaytis MA, Bhattacharya BD, Godhantaraman N. Trace metal bioaccumulation by soft-bottom polychaetes (Annelida) of Sundarban mangrove wetland, India and their potential use as contamination indicator. Bull Environ Contam Toxicol, 2010, 85(5): 492-496

[4]	Alongi DM, Wattayakorn G, Boyle S, Tirendi F, Payn C, Dixon P. Influence of roots and climate on mineral and trace element storage and flux in tropical mangrove soils. Biogeochemistry, 2004, 69: 105-123

[5]	Araújo PRM, Biondi CM, do Nascimento CWA, Silva FBV, Ferreira DK de M (2021) Assessing the spatial distribution and ecologic and human health risks in mangrove soils polluted by Hg in northeastern Brazil. Chemosphere 266:129019. https://doi.org/10.1016/j.chemosphere.2020.129019

[6]	Bastos WR, Malm O, Pfeiffer WC, Cleary D. Establishment and analytical quality control of laboratories for Hg determination in biological and geological samples in the Amazon, Brazil. Cienc Cult, 1998, 50: 255-260

[7]	Benoit JM, Gilmour CC, Mason RP. The influence of sulfide on solid-phase mercury bioavailability for methylation by pure cultures of Desulfobulbus propionicus. Environ Sci Technol, 2001, 35(1): 127-132

[8]	Buruaem LM, Hortellani MA, Sarkis JE, Costa-Lotufo LV, Abessa DMS. Contamination of port zone sediments by metals from large marine ecosystems of Brazil. Mar Pollut Bull, 2012, 64(3): 479-488

[9]	Canham R, Gonzalez-Prieto AM, Elliott JE. Mercury exposure and toxicological consequences in fish and fish-eating wildlife from anthropogenic activity in Latin America. Integr Environ Assess Manag, 2021, 17(1): 13-26

[10]	Chen C-W, Chen C-F, Dong C-D. Contamination and potential ecological risk of mercury in sediments of Kaohsiung River mouth, Taiwan. Int J Environ Sci Dev, 2012, 3(6): 603-615

[11]	Chiappetta JM, Machado W, Santos JM, Lessa JA. Trace metal bioavailability in sediments from a reference site, Ribeira Bay. Brazil Marine Pollution Bulletin, 2016, 106(1–2): 395-399

[12]	Chmura GL, Anisfeld SC, Cahoon DR, Lynch JC. Global carbon sequestration in tidal, saline wetland soils. Global Biogeochem Cycles, 2003, 17(4): 1111

[13]	Davaulter V, Rognerud S. Heavy metal pollution in sediments of the Pasvik River drainage. Chemosphere, 2001, 4219-18

[14]	De Paula F, Mozeto AA. Biogeochemical evolution of trace elements in a pristine watershed in the Brazilian southeastern coastal region. Appl Geochem, 2001, 16(10): 1139-1151

[15]	Ding Z, Liu J, Li L, Lin H, Wu H, Hu Z. Distribution and speciation of mercury in surficial sediments from main mangrove wetlands in China. Mar Pollut Bull, 2009, 58(9): 1319-1325

[16]	Dioses Puelles J, García-García R, Bermejo Requena LA (2023). Tipos de cobertura vegetal del Área Natural Protegida “Santuario Nacional Los Manglares de Tumbes”, Tumbes, Perú. Manglar 20(2): 177–183. https://doi.org/10.57188/manglar.2023.020

[17]	Duan D, Lei P, Lan W, Li T, Zhang H, Zhong H, Pan K. Litterfall-derived organic matter enhances mercury methylation in mangrove sediments of South China. Sci Total Environ, 2021, 765: 142763

[18]	Duarte CM, Losada IJ, Hendriks IE, Mazarrasa I, Marbà N. The role of coastal plant communities for climate change mitigation and adaptation. Nat Clim Chang, 2013, 3(11): 961-968

[19]	Gagnon C, Pelletier E, Mucci A. Behaviour of anthropogenic mercury in coastal marine sediments. Mar Chem, 1997, 59(3–4): 159-176

[20]	García-Ordiales E, Correa N, Álvarez-León R, Quintero M, Aragón S, Correa-Metrio A. Effect of environmental variables on mercury accumulation in sediments of an anthropogenically impacted tropical estuary (Buenaventura Bay, Colombian Pacific). Environ Monit Assess, 2023, 195: 1316

[21]	Gworek B, Bemowska-Kałabun O, Kijeńska M. Mercury in marine and oceanic waters: A review. Water Air Soil Pollut, 2016, 227: 371

[22]	Harbison P. Mangrove muds – a sink and source for trace metals. Mar Pollut Bull, 1986, 17(5): 273-276

[23]	Hsu-Kim H, Kucharzyk KH, Zhang T, Deshusses MA. Mechanisms regulating mercury bioavailability for methylating microorganisms in the environment. Environ Sci Technol, 2013, 47(6): 2441-2456

[24]	Huerta-Díaz MA, Morse JW. A quantitative method for determination of trace metal concentration in sedimentary pyrite. Mar Chem, 1990, 29: 119-144

[25]	Jänes H, Macreadie PI, Ermgassen PSEZ, Gair JR, Treby S, Reeves S, Nicholson E, Ierodiaconou D, Carnell P. Quantifying fisheries enhancement from coastal vegetated ecosystems. Ecosystem Serv, 2020, 43: 101105

[26]	Jinks KI, Rasheed MA, Brown CJ, Olds AD, Schlacher TA, Sheaves M, York PH, Connolly RM. Saltmarsh grass supports fishery food webs in subtropical Australian estuaries. Estuar Coast Shelf Sci, 2020, 238: 106719

[27]	Lacerda LD (1998). Biogeochemistry of trace metals and diffuse pollution in mangrove ecosystems. International Society for Mangrove Ecosystems

[28]	Lacerda LD, Marins RV, Mounier S, Benaim J. Dissolved mercury concentrations and reactivity in mangrove waters from the Itacurussa experimental forest, Sepetiba Bay. SE Brazil Wetlands Ecology and Management, 2001, 9(4): 323-331

[29]	Lacerda LD, Soares TM, Costa BGB, Godoy MDP. Mercury emission factors from intensive shrimp aquaculture and their relative importance to the Jaguaribe River Estuary, NE Brazil. Bull Environ Contam Toxicol, 2011, 87(6): 657-661

[30]	Lacerda LD, Marins RV, Dias FJS. An Arctic paradox: Response of fluvial Hg inputs and bioavailability to global climate change in an extreme coastal environment. Front Earth Sci, 2020, 8: 93

[31]	Lagos P, Silva Y, Nickl E, Mosquera K. El Niño–related precipitation variability in Peru. Adv Geosci, 2008, 14: 231-237

[32]	Lavado W, Espinoza JC. Impactos de El Niño y La Niña en las lluvias del Perú (1965–2007). Rev Bras Meteorol, 2014, 29(2): 171-182

[33]	Lei P, Zhong H, Duan D, Pan K. A review on mercury biogeochemistry in mangrove sediments: hotspots of methylmercury production?. Sci Total Environ, 2019, 680: 140-150

[34]	Leventhal J, Taylor C. Comparison of methods to determine degree of pyritization. Geochim Cosmochim Acta, 1990, 54: 2621-2625

[35]	Li C, Wang H, Liao X, Xiao R, Liu K, Bai J, Li B, He Q (2022). Heavy metal pollution in coastal wetlands: A systematic review of studies globally over the past three decades. J Hazard Mat 424(Part A):127312. https://doi.org/10.1016/j.jhazmat.2021.127312

[36]	Lino AS, Galvão PMA, Longo RTL, Azevedo-Silva CE, Dorneles PR, Torres JPM, Malm O. Metal bioaccumulation in consumed marine bivalves in Southeast Brazilian coast. J Trace Elem Med Biol, 2016, 34: 50-55

[37]	Liu Z, Cui B, He Q (2016) Shifting paradigms in coastal restoration: Six decades’ lessons from China. Sci Total Environ 566–567, 205–214. https://doi.org/10.1016/j.scitotenv.2016.05.049

[38]	Long ER, MacDonald DD, Smith SL, Calder FD. Incidence of adverse biological effects within ranges of chemical concentrations in marine and estuarine sediments. Environ Manage, 1995, 19: 81-97

[39]	Loring DH, Rantala RTT. Manual for the geochemical analyses of marine sediments and suspended particulate matter. Earth Sci Rev, 1992, 32(3): 235-283

[40]	Ma RF, Cheng H, Inyang A, Wang M, Wang YS. Distribution and risk of mercury in the sediments of mangroves along the South China coast. Ecotoxicology, 2020, 29: 641-649

[41]	Machado W, Moscatelli M, Rezende LG, Lacerda LD. Mercury, zinc, and copper accumulation in mangrove sediments surrounding a large landfill in Southeast Brazil. Environ Pollut, 2002, 120(3): 455-461

[42]	Machado W, Sanders CJ, Santos IR, Sanders LM, Silva Filho EV, Silva WL. Mercury dilution by autochthonous organic matter in a fertilized mangrove wetland. Environ Pollut, 2016, 213: 30-35

[43]	Malm O, Pfeiffer WC, Bastos WR, Souza CMM. Utilização do acessório de geração de vapor frio para análise de mercúrio em investigações ambientais por espectrofotometria de absorção atômica. Revista Brasileira De Progresso Em Ciências, 1989, 41: 88-92

[44]	Martínez Cabrera R. Presión antrópica y su relación con la susceptibilidad del Santuario Nacional Los Manglares de Tumbes, 2000–2020. Cátedra Villarreal Posgrado, 2022

[45]	Montero P. Calidad ambiental de la bahía de Puerto Pizarro y del ecosistema de manglar, Tumbes, Perú. Inf Inst Mar Peru, 2019, 46(4): 636-660

[46]	Morse JW. Interactions of trace metals with authigenic sulfide minerals: Implications for their bioavailability. Mar Chem, 1994, 46(1–4): 1-6

[47]	Nordlund LM, Unsworth RKF, Gullström M, Cullen-Unsworth LC. Global significance of seagrass fishery activity. Fish Fish, 2018, 19(3): 399-412

[48]	Pérez A, Gutiérrez D, Saldarriaga M, Sanders CJ. Hydrological controls on the biogeochemical dynamics of a Peruvian mangrove system. Hydrobiologia, 2017, 803: 69-86

[49]	Pérez A, Gutiérrez D, Saldarriaga MS, Sanders CJ. Tidally driven sulfidic conditions in Peruvian mangrove sediments. Geo-Mar Lett, 2018, 38(6): 457-465

[50]	Pérez A, Machado W, Gutiérrez D, Saldarriaga MS, Sanders CJ. Shrimp farming influence on carbon and nutrient accumulation within Peruvian mangrove sediments. Estuar Coast Shelf Sci, 2020, 243: 106879

[51]	Pérez A, Machado W, Sanders CJ. Anthropogenic and environmental influences on nutrient accumulation in mangrove sediments. Mar Pollut Bull, 2021, 165: 112174

[52]	Sanders CJ, Santos IR, Barcellos R, Silva Filho EV. Elevated concentrations of dissolved Ba, Fe and Mn in a mangrove subterranean estuary: consequence of sea level rise?. Cont Shelf Res, 2012, 43: 86-94

[53]	Selvaggi R, Damianic B, Goretti E, Pallottini M, Petroselli C, Beatrice M, La Porta G, Cappelletti D. Evaluation of geochemical baselines and metal enrichment factor values through high ecological quality reference points: A novel methodological approach. Environ Sci Pollut Res, 2020, 27: 930-940

[54]	Selvaraj K, Ram Mohan V, Szefer P. Evaluation of metal contamination in coastal sediments of the Bay of Bengal, India: geochemical and statistical approaches. Mar Pollut Bull, 2004, 49(3): 174-185

[55]	Shen J, Feng Q, Algeo TJ, Liu J, Zhou C, Wei W, Them TR, Gill BC, Chen J. Sedimentary host phases of mercury (Hg) and implications for use of Hg as a volcanic proxy. Earth Planet Sci Lett, 2020, 543: 116333

[56]	Shi C, Yu L, Chai M, Niu Z, Li R. The distribution and risk of mercury in Shenzhen mangroves, representative urban mangroves affected by human activities in China. Mar Pollut Bull, 2020, 151: 110866

[57]

Zapata-Cruz M, García Seminario R, Hidalgo Mogollón A, Vieyra-Peña EG, Sánchez Suárez H, Ordinola-Zapata A (2024). Características estructurales del mangle rojo (Rhizophora mangle) en el manglar de Puerto Pizarro (Tumbes, Perú). FIGEMPA: Investigación y Desarrollo 17(1):1–15. https://doi.org/10.29166/revfig.v17i1.5673