Abstract
Heavy metal contamination commonly appears in mining areas and volcanic watersheds due to the acidic drainage water. Under the hydrochemical condition, the solar photocycle would result in changes of the water temperature, in photosynthesis and in iron photoreduction, which leads to substantial hydrochemical fluctuations, especially for heavy metals. It is important to consider the daily variations in water quality when developing a hydrochemical monitoring plan for an area with highly developed agriculture, such as the Tatun Volcano Group watershed area in this study. The results show that the water chemistry is highly complicated by both solar photocycles and hydrochemical fluctuations in the upstream area. Using principal component analysis, the contributions from the two factors can be successfully separated. During the daytime, the photocycle results in the formation of aluminum hydroxide, which can remove heavy metals from water. Consequently, the content of heavy metals, including As, Cu, Ni, Co and Ba, increases after sunset and can reach a maximum before sunrise, while Fe behaves inversely due to the photoreduction. The variation of As during a diel cycle can reach 97%. However, the content of most of the heavy metals during diel cycle is incomparable with those in the earlier studies due to the formation of aluminum hydroxide instead of iron hydroxide. The other significant factor, hydrochemical fluctuation, can explain the variation of major components in water including Cl, SO4. Rare earth elements (REEs) were also analyzed and can be an excellent natural tracer in this study. The distribution of REEs shows a depletion of light REEs and an even normalized concentration of middle and heavy REEs. It is theorized that the REEs in the water in this study derive mainly from the reservoir rock of geothermal water. In a hydrochemical monitoring plan, REEs can be an indicator for identifying an anthropogenic source.
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References
Anazawa K, Ohmori H (2005) The hydrochemistry of surface waters in Andesitic volcanic area, Norikura volcano, central Japan. Chemosphere 59:605–615
Brezonik PL, Fulkerson-Brekken J (1998) Nitrate-induced photolysis in natural waters: controls on concentrations of hydroxyl radical photo-intermediates by natural scavenging agents. Environ Sci Technol 32:3004–3010
Burns D, McDonnell JJ, Hooper RP (2001) Quantifying contributions to storm runoff through end-member mixing analysis and hydrologic measurements at the Panola Mountain Research Watershed (Georgia, USA). Hydrol Process 15:1903–1924
Castorina F, Masi U (2015) Rare earth elements and Sr–Nd isotopes in mosses from Romagna (Italy) and their environmental significance. Biogeochemistry 123:251–263
Christophersen N, Hooper RP (1992) Multivariate analysis of stream water chemical data: the use of principal components analysis for the end-member mixing problem. Water Resour Res 28:99–107
Cuoco E, Spagnuolo A, Balagizi C, De Francesco S, Tassi F, Vaselli O, Tedesco D (2013) Impact of volcanic emissions on rainwater chemistry: the case of Mt. Nyiragongo in the Virunga volcanic region (DRC). J Geochem Explor 125:69–79
Davranche M, Grybos M, Gruau G, Pédrot M, Dia A, Marsac R (2011) Rare earth element patterns: a tool for identifying trace metal sources during wetland soil reduction. Chem Geol 284:127–137
Drahota P, Nováková B, Matoušek T, Mihaljevič M, Rohovec J, Filippi M (2013) Diel variation of arsenic, molybdenum and antimony in a stream draining natural As geochemical anomaly. Appl Geochem 31:84–93
Equeenuddin SM, Tripathy S, Sahoo PK, Panigrahi MK (2013) Metal behavior in sediment associated with acid mine drainage stream: role of pH. J Geochem Explor 124:230–237
Gammons CH, Nimick DA, Parker SR, Cleasby TE, McCleskey RB (2005a) Diel behavior of iron and other trace metals in a mountain stream with acidic to neutral pH: Fisher Creek, Montana, USA. Geochim Cosmochim Acta 69:2505–2516
Gammons CH, Nimick DA, Wood SA (2005b) Diel behavior of rare earth elements in a mountain stream with acidic to neutral pH. Geochim Cosmochim Acta 69:3747–3758
Gammons CH, Nimick DA, Parker SR (2015) Diel cycling of trace elements in streams draining mineralized areas—a review. Appl Geochem 57:35–44
Göb S, Loges A, Nolde N, Bau M, Jacob DE, Markl G (2013) Major and trace element compositions (including REE) of mineral, thermal, mine and surface waters in SW Germany and implications for water–rock interaction. Appl Geochem 33:127–152
Irawan DE, Puradimaja DJ, Notosiswoyo S, Soemintadiredja P (2009) Hydrogeochemistry of volcanic hydrogeology based on cluster analysis of Mount Ciremai, West Java, Indonesia. J Hydrol 376:221–234
Kay RT, Groschen GE, Cygan G, Dupré DH (2011) Diel cycles in dissolved barium, lead, iron, vanadium, and nitrite in a stream draining a former zinc smelter site near Hegeler, Illinois. Chem Geol 283:99–108
Kimball BA, McKnight DM, Wetherbee GA, Harnish RA (1992) Mechanisms of iron photoreduction in a metal-rich, acidic stream (St. Kevin Gulch, Colorado, U.S.A.). Chem Geol 96:227–239
Liu F, Williams MW, Caine N (2004) Source waters and flowpaths in a seasonally snow-covered catchment, Colorado Front Range, USA. Water Resour Res 40:W09401
López DL, Bundschuh J, Birkle P, Armienta MA, Cumbal L, Sracek O, Cornejo L, Ormachea M (2012) Arsenic in volcanic geothermal fluids of Latin America. Sci Total Environ 429:57–75
Lu HY (2014) Application of water chemistry as a hydrological tracer in a volcano catchment area: a case study of the Tatun Volcano Group, North Taiwan. J Hydrol 511:825–837
Matlock MM, Howerton BS, Atwood DA (2002) Chemical precipitation of heavy metals from acid mine drainage. Water Res 36:4757–4764
Nimick DA, Gammons CH, Cleasby TE, Madison JP, Skaar D, Brick CM (2003) Diel cycles in dissolved metal concentrations in streams: occurrence and possible causes. Water Resour Res 39:1247
Nimick DA, Gammons CH, Parker SR (2011) Diel biogeochemical processes and their effect on the aqueous chemistry of streams: a review. Chem Geol 283:3–17
Ogawa Y, Ishiyama D, Shikazono N, Iwane K, Kajiwara M, Tsuchiya N (2012) The role of hydrous ferric oxide precipitation in the fractionation of arsenic, gallium, and indium during the neutralization of acidic hot spring water by river water in the Tama River watershed, Japan. Geochim Cosmochim Acta 86:367–383
Rieuwerts JS, Mighanetara K, Braungardt CB, Rollinson GK, Pirrie D, Azizi F (2014) Geochemistry and mineralogy of arsenic in mine wastes and stream sediments in a historic metal mining area in the UK. Sci Total Environ 472:226–234
Sarmiento AM, Caraballo MA, Sanchez-Rodas D, Nieto JM, Parviainen A (2012) Dissolved and particulate metals and arsenic species mobility along a stream affected by Acid Mine Drainage in the Iberian Pyrite Belt (SW Spain). Appl Geochem 27:1944–1952
Scott DT, Runkel RL, McKnight DM, Voelker BM, Kimball BA, Carraway ER (2003) Transport and cycling of iron and hydrogen peroxide in a freshwater stream: influence of organic acids. Water Resour Res 39:1308
Seto M, Akagi T (2008) Chemical condition for the appearance of a negative Ce anomaly in stream waters and groundwaters. Geochem J 42:371–380
Stille P, Pierret M-C, Steinmann M, Chabaux F, Boutin R, Aubert D, Pourcelot L, Morvan G (2009) Impact of atmospheric deposition, biogeochemical cycling and water–mineral interaction on REE fractionation in acidic surface soils and soil water (the Strengbach case). Chem Geol 264:173–186
Suteerapataranon S, Bouby M, Geckeis H, Fanghänel T, Grudpan K (2006) Interaction of trace elements in acid mine drainage solution with humic acid. Water Res 40:2044–2054
Tang WW, Zeng GM, Gong JL, Liang J, Xu P, Zhang C, Huang BB (2014) Impact of humic/fulvic acid on the removal of heavy metals from aqueous solutions using nanomaterials: a review. Sci Total Environ 468–469:1014–1027
Vázquez-Ortega A, Perdrial J, Harpold A, Zapata-Ríos X, Rasmussen C, McIntosh J, Schaap M, Pelletier JD, Brooks PD, Amistadi MK, Chorover J (2015) Rare earth elements as reactive tracers of biogeochemical weathering in forested rhyolitic terrain. Chem Geol 391:19–32
Wang KL, Chung SL, O’Reilly SY, Sun SS, Shinjo R, Chen C-H (2004) Geochemical constraints for the genesis of post-collisional magmatism and the geodynamic evolution of the Northern Taiwan region. J Petrol 5:975–1011
Wu F, Deng N (2000) Photochemistry of hydrolytic iron(III) species and photoinduced degradation of organic compounds. A minireview. Chemosphere 41:1137–1147
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This study is supported by research grants from National Science Council, Taiwan (NSC103-2116-M-194-003-).
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Kao, SY., Lu, HY., Liou, TS. et al. Study of diel hydrochemical variation in a volcanic watershed using principal component analysis: Tatun Volcano Group, North Taiwan. Environ Earth Sci 76, 193 (2017). https://doi.org/10.1007/s12665-017-6491-2
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DOI: https://doi.org/10.1007/s12665-017-6491-2