Carbonate chemistry and air-sea CO₂ exchange in a highly urbanized tropical coastal system

Muthukumar Chandrasekaran; M. Durga Bharathi; Vengateshwaran Thasu Dinakaran; Henciya Santhaseelan; S. Balasubramaniyan; Deviram Garlapati; B. Charan Kumar; Arthur James Rathinam; Ramu Karri; Ramanamurthy MV

doi:10.1007/s44218-025-00118-5

Anthropocene Coasts ›› 2025, Vol. 8 ›› Issue (1) :40 DOI: 10.1007/s44218-025-00118-5

Research Article

research-article

Carbonate chemistry and air-sea CO₂ exchange in a highly urbanized tropical coastal system

Author information +

History +

PDF

Abstract

Tuticorin Bay (TB), a shallow semi-enclosed coastal system on the southeast coast of India, exemplifies the escalating challenges faced by urbanized tropical bays, where anthropogenic stressors interact with complex biogeochemical processes. This study investigates the spatial and seasonal variability of carbonate system dynamics and air–sea carbon dioxide (CO₂) fluxes across three hydrologically distinct periods: the southwest monsoon (SWM, August 2018), northeast monsoon (NEM, October 2018), and summer (SUM, May 2019). Surface waters exhibited a wide range of pCO₂ (380–1036 μatm), revealing spatial heterogeneity across distinct biogeochemical regimes. Elevated pCO₂ levels in most regions confirm the bay’s dominant role as a CO₂ source; however, localized undersaturation (~ 380 μatm) during the SWM indicates short-term CO₂ uptake, associated with intense biological production and high chlorophyll-a concentrations (> 50 μg L⁻¹) in the nutrient-enriched north region of the bay. In contrast, the southern bay showed persistently high pCO₂, driven by elevated temperatures (> 36 °C) and enhanced respiration promoted by thermal effluent discharges. Dissolved Inorganic Carbon (DIC) exhibited non-conservative behaviour across seasons, with ΔDIC ranging from –487 to + 639 μmol kg⁻¹, highlighting the influence of terrestrial inputs and local metabolic processes. Peak air–sea CO₂ fluxes reached 17.23 mmol C m⁻² d⁻¹ during SUM, particularly in low-oxygen zones (< 60% saturation) of the southern bay. These findings demonstrate how seasonally shifting physical conditions and localized anthropogenic pressures govern CO₂ dynamics in a spatially confined tropical bay, underscoring the need for high-resolution assessments of such vulnerable systems to improve regional carbon budget estimates.

Keywords

Carbon cycle / Tuticorin / Carbonate chemistry / Seasonal Variation / CO₂ fluxes

Cite this article

Download citation ▾

Muthukumar Chandrasekaran, M. Durga Bharathi, Vengateshwaran Thasu Dinakaran, Henciya Santhaseelan, S. Balasubramaniyan, Deviram Garlapati, B. Charan Kumar, Arthur James Rathinam, Ramu Karri, Ramanamurthy MV. Carbonate chemistry and air-sea CO₂ exchange in a highly urbanized tropical coastal system. Anthropocene Coasts, 2025, 8(1): 40 DOI:10.1007/s44218-025-00118-5

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]	Abril G, Etcheber H, Delille B, Borges MFAV. Carbonate dissolution in the turbid and eutrophic Loire estuary. Mar Ecol Prog Ser, 2003, 259: 129-138.

[2]	Asha PS, Diwakar K. Hydrobiology of the inshore waters off Tuticorin in the Gulf of Mannar. J Mar Biol Assoc India, 2007, 49(1): 7-11

[3]	Balakrishnan S, Chelladurai G, Mohanraj J, Poongodi J. Seasonal variations in physico-chemical characteristics of Tuticorin coastal waters, southeast coast of India. Appl Water Sci, 2017, 7: 1881-1886.

[4]	Bauer JE, Cai W-J, Raymond PA, Bianchi TS, Hopkinson CS, Regnier PA. The changing carbon cycle of the coastal ocean. Nature, 2013, 504(7478): 61-70.

[5]	Benson BB, Krause DJr. The concentration and isotopic fractionation of oxygen dissolved in freshwater and seawater in equilibrium with the atmosphere 1. Limnol Oceanogr, 1984, 29(3): 620-632.

[6]	Bharathi MD, Muthukumar C, Sathishkumar RS, Ramu K, Murthy MR. First report on the occurrence of Gonyaulax polygramma bloom during the onset of Noctiluca scintillans bloom along the Tuticorin coast, southeast coast of India. Mar Pollut Bull, 2023, 195: 115523

[7]	Bharathi MD, Patra S, Sundaramoorthy S, Madeswaran P, Chandrasekar D, Sundaramanickam A (2018) Seasonal variability in plankton food web composition in Tuticorin coastal waters, south east coast of India. Mar Poll Bull 137:408–417.

[8]	Borges AV, Abril G (2011) Carbon dioxide and methane dynamics in estuaries. In Treatise on estuarine and coastal science, vol. 5, ed. E. Wolanski and D.S. McLusky, 119–161. Waltham: Academic.

[9]	Borges AV (2011) Present Day Carbon Dioxide Fluxes in the Coastal Ocean and Possible Feedbacks Under Global Change. In: Duarte, P., Santana-Casiano, J. (eds) Oceans and the Atmospheric Carbon Content. Springer, Dordrecht. https://doi.org/10.1007/978-90-481-9821-4_3

[10]

Bouillon S, Frankignoulle M, Dehairs F, Velimirov B, Eiler A, Abril G, Etcheber H, Borges AV (2003) Inorganic and organic carbon biogeochemistry in the Gautami Godavari estuary (Andhra Pradesh, India) during pre-monsoon: The local impact of extensive mangrove forests. Global Biogeochemical Cycles 17(4):1114. https://doi.org/10.1029/2002GB002026.

[11]	Cai WJ. Estuarine and coastal ocean carbon paradox: CO2 sinks or sites of terrestrial carbon incineration?. Ann Rev Mar Sci, 2011, 3(1): 123-145.

[12]	Cai WJ, Dai M, Wang Y, Zhai W, Huang T, Chen S, Zhang F, Chen Z, Wang Z. The biogeochemistry of inorganic carbon and nutrients in the Pearl River estuary and the adjacent Northern South China Sea. Cont Shelf Res, 2004, 24(12): 1301-1319.

[13]	Carritt DE, Carpenter JH (1966) Comparison and evaluation of currently employed modifications of Winkler method for determining dissolved oxygen in seawater—a Nasco report. J Mar Res 24:286–318

[14]	Cao Z, Yang W, Zhao Y, Han Y, Wang Z, Liu S, Yang S. Seasonal variability of pCO₂ in the global coastal ocean. Biogeosciences, 2020, 17(16): 4135-4148.

[15]	Chanda A, Das S, Bhattacharyya S, Akhand A, Das I, Samanta S, Choudhury SB, Hazra S. CO2 effluxes from an urban tidal river flowing through two of the most populated and polluted cities of India. Environ Sci Pollut Res Int, 2020, 27(24): 30093-30107.

[16]	Cotovicz LCJr, Knoppers BA, Brandini N, Costa Santos SJ, Abril G. A strong CO₂ sink enhanced by eutrophication in a tropical coastal embayment (Guanabara Bay, Rio de Janeiro, Brazil). Biogeosciences, 2015, 12(20): 6125-6146.

[17]	Dickson AG, Sabine CL, Christian JR (2007) Guide to best practices for ocean CO2 measurements, vol 3. PICES Special Publications, p 191

[18]

Fennel K, Alin SR, Barbero L, Evans W, Bourgeois T, Cooley SR, Dunne J, Feely RA, Hernandez-Ayon JM, Hu X, Lohrenz SE, Muller-Karger F, Najjar RG, Robbins L, Shadwick E, Siedlecki SA, Steiner N, Sutton AJ, Turk D, Zawadzki A. Carbon cycling in the North American coastal ocean: A synthesis. Biogeosciences, 2019, 16(3): 691-708.

[19]	Gupta GVM, Sarma VVSS, Robin RS, Raman AV, Jai Kumar M, Rakesh M, Subramanian BR. Influence of net ecosystem metabolism in transferring riverine organic carbon to atmospheric CO2 in a tropical coastal lagoon (Chilka Lake, India). Biogeochemistry, 2008, 87(3): 265-285.

[20]	Gupta GVM, Thottathil SD, Balachandran KK, Madhu NV, Madeswaran P, Nair S. CO₂ supersaturation and net heterotrophy in a tropical estuary (Cochin, India): influence of anthropogenic effect: carbon dynamics in tropical estuary. Ecosystems, 2009, 12: 1145-1157.

[21]	IMD (2015) India Meteorological Department. Climatological Normals (1981–2010). Government of India, Ministry of Earth Sciences

[22]	Jiang LQ, Cai WJ, Wang Y, Bauer JE. Influence of terrestrial inputs on continental shelf carbon dioxide. Biogeosciences, 2013, 10(2): 839-849.

[23]	Kailasam M, Sivakami S. Effect of thermal effluent discharge on benthic fauna off Tuticorin bay, south east coast of India. Indian J Mar Sci, 2004, 33: 194-201

[24]	Kanuri VV, Rao GD, Kumaraswami M, Naidu SA, Patra S, Ranga Rao V, Ramu K. Scales and drivers of seasonal pCO2 dynamics and net ecosystem exchange along the coastal waters of south-eastern Arabian sea. Mar Pollut Bull, 2017, 121: 372-380.

[25]	Krishna MS, Viswanadham R, Prasad MH, Kumari VR, Sarma VV. Export fluxes of dissolved inorganic carbon to the northern Indian Ocean from the Indian monsoonal rivers. Biogeosciences, 2019, 16(2): 505-519.

[26]	Kubo A, Maeda Y, Kanda J. A significant net sink for CO2 in Tokyo Bay. Sci Rep, 2017, 7: 4-5.

[27]	Laruelle GG, Dürr HH, Lauerwald R, Hartmann J, Slomp CP, Goossens N, Regnier P. Continental shelves as a variable but increasing global sink for atmospheric carbon dioxide. Nat Commun, 2017, 8: 14015

[28]	Lee DI, Choi JM, Lee YG, Lee MO, Lee WC, Kim JK. Coastal environmental assessment and management by ecological simulation in Yeoja Bay, Korea. Estuar Coast Shelf Sci, 2008, 80(4): 495-508.

[29]	Lewis, E., Wallace, D., and Allison, L. J. (1998). Program Developed for CO2 System Calculations. Environmental Sciences Division Publication No. 4735; Carbon Dioxide Information Analysis Center; Oak Ridge National Laboratory, Oak Ridge, TN

[30]	Li Y, Yang X, Han P, Xue L, Zhang L. Controlling mechanisms of surface partial pressure of CO2 in Jiaozhou Bay during summer and the influence of heavy rain. J Mar Syst, 2017, 173: 49-59.

[31]	Li Y, Yang H, Zhang L, Yang X, Zang H, Fan W, Wang G (2020) The spatiotemporal variation and control mechanism of surface pCO2 in winter in Jiaozhou Bay, China. Cont Shelf Res 206:104208.

[32]	Liu XY, Yang XF, Li YX, Zhang LJ. Sea surface pCO2 in an urbanized coastal system (Jiaozhou Bay, China) during summer. Mar Pollut Bull, 2019, 146: 767-778.

[33]	Maher DT, Call M, Santos IR, Sanders CJ. Submarine groundwater discharge and associated fluxes of alkalinity and dissolved carbon into Moreton Bay (Australia) estimated via radium isotopes. Mar Chem, 2018, 174: 1-12.

[34]	Meiaraj C, Jeyapriya SP (2019) Marine water quality studies at Tuticorin harbour coastal area. Indian J Mar Sci 48(6).

[35]	Millero FJ, Graham TB, Huang F, Bustos-Serrano H, Pierrot D. Dissociation constants of carbonic acid in seawater as a function of salinity and temperature. Mar Chem, 2006, 100(1–2): 80-94.

[36]	Muduli PR, Kanuri VV, Robin RS, Kumar BC, Patra S, Raman AV, Rao GN, Subramanian BR. Spatio-temporal variation of CO₂ emission from Chilika Lake, a tropical coastal lagoon, on the east coast of India. Estuar Coast Shelf Sci, 2012, 113: 305-313.

[37]	Mukhopadhyay SK, Biswas H, De TK, Sen S, Jana TK. Seasonal effects on the air–water carbon dioxide exchange in the Hooghly estuary, NE coast of Bay of Bengal, India. J Environ Monit, 2002, 4(4): 549-552.

[38]	Muthukumar C, Balasubramaniyan S, Garlapati D, Bharathi MD, Kumar BC, James RA, Ramanamurthy MV. Impact of untreated sewage and thermal effluent discharges on the air-sea CO2 fluxes in a highly urbanized tropical coastal region. Mar Pollut Bull, 2022, 175: 113166

[39]	Parthasarathy A, Natesan U. Coastal vulnerability assessment: a case study on erosion and coastal change along Tuticorin, Gulf of Mannar. Nat Hazards, 2015, 75(2): 1713-1729.

[40]	Pattanaik S, Roy R, Sahoo RK, Choudhury SB, Panda CR, Satapathy DR, Majhi A, D’Costa PM, Sai MS. Air-sea CO2 dynamics from tropical estuarine system Mahanadi, India. Reg Stud Mar Sci, 2020, 36: 101284

[41]	Pitchaikani JS, Ananthan G, Sudhakar M. Studies on the effect of coolant water effluent of Tuticorin thermal power station on hydro biological characteristics of Tuticorin Coastal Waters, South East Coast of India. Curr Res J Biol Sci, 2010, 2(2): 118-123

[42]	Redfield, A.C., Ketchum, B.H., Richards, F.A., 1963. The Influence of Organisms on the Composition of Seawater. In: Hill, M.N. (Ed.), The Sea. Volume 2. Wiley-Interscience, New York, p.26–77.

[43]

Regnier P, Friedlingstein P, Ciais P, Mackenzie FT, Gruber N, Janssens IA, Laruelle GG, Lauerwald R, Luyssaert S, Andersson AJ, Arndt S, Arnosti C, Borges AV, Dale AW, Gallego-Sala A, Goddéris Y, Goossens N, Hartmann J, Heinze C, Zhong S. Anthropogenic perturbationof the carbon fluxes from land to ocean. Nature Geoscience, 2013, 6(8): 597-607.

[44]	Regnier P, Resplandy L, Najjar RG, Ciais P. The land-to-ocean loops of the global carbon cycle. Nature, 2022, 603(7901): 401-410.

[45]	Sarma VVSS, Gupta SNM, Babu PVR, Acharya T, Harikrishnachari N, Vishnuvardhan K, Kumar MD. Influence of river discharge on plankton metabolic rates in the tropical monsoon driven Godavari estuary, India. Estuar Coast Shelf Sci, 2009, 85(4): 515-524.

[46]	Sarma VVSS, Kumari VR, Srinivas TNR, Krishna MS, Ganapathi P, Murty VSN (2018) East India Coastal Current controls the dissolved inorganic carbon in the coastal Bay of Bengal. Mar Chem 205:37–47.

[47]	Sarma VV, Kumar MD, George MD, Rajendran A (1996) Seasonal variations in inorganic carbon components in the central and eastern Arabian Sea. Curr Sci 71(11):852–856

[48]	Sarma VVSS, Kumar NA, Prasad VR, Venkataramana V, Appalanaidu S, Sridevi B, Kumar BSK, Bharati MD, Subbaiah CV, Acharyya T, Rao GD. High CO2 emissions from the tropical Godavari estuary (India) associated with monsoon river discharges. Geophys Res Lett, 2011, 38(8): n/a.

[49]	Sarma VVSS, Viswanadham R, Rao GD, Prasad VR, Kumar BSK, Naidu SA, Kumar NA, Rao DB, Sridevi T, Krishna MS, Reddy NPC, Sadhuram Y, Murty TVR (2012) Carbon dioxide emissions from Indian monsoonal estuaries. Geophys Res Lett 39:L03602. https://doi.org/10.1029/2011GL050709

[50]	Sathishkumar RS, Sundaramanickam A, Sahu G, Mohanty AK, Ramesh T, Khan SA. Intense bloom of the diatom Hemidiscus hardmanianus (Greville) in relation to water quality and plankton communities in Tuticorin coast, Gulf of Mannar, India. Mar Pollut Bull, 2021, 163: 111757

[51]	Schlitzer Reiner, (2021) Ocean Data View. https://odv.awi.de

[52]	Sekar CP, Poongothai S, Neelakantan MA. Impact of industrial pollution on the physicochemical characteristics of sea water in Thoothukudi coastal area. Rasayan J Chem, 2009, 2(4): 912-919. DOI:

[53]	Shanthi R, Poornima D, Naveen M, Thangaradjou T, Choudhury SB, Rao KH, Dadhwal VK (2016) Air-sea CO2 flux pattern along the southern Bay of Bengal waters. Dynamics of Atmospheres and Oceans 76:14–28.

[54]	Strickland JDH, Parsons TR (1972) A practical handbook of seawater analysis. https://doi.org/10.25607/OBP-1791

[55]	Swain S, Pattanaik S, Chanda A, Akhand A, Sahu RN, Majhi A, Panda CR, Satapathy DR, Sahoo RK, Roy R. Multi-annual variability of pCO₂ (aq) and air-water CO₂ flux in the mangrove-dominated Dhamra Estuary draining into the Bay of Bengal (India). Environ Sci Pollut Res, 2023, 30(51): 111021-111038.

[56]	Takahashi T, Olafsson J, Goddard JG, Chipman DW, Sutherland SC. Seasonal variation of CO₂ and nutrients in the high-latitude oceans: a comparative study. Glob Biogeochem Cycles, 1993, 7: 843-878.

[57]	Thottathil SD, Balachandran KK, Gupta GVM, Madhu NV, Nair S. Influence of allochthonous input on autotrophic–heterotrophic switch-over in shallow waters of a tropical estuary (Cochin Estuary), India. Estuar Coast Shelf Sci, 2008, 78(3): 551-562.

[58]	Wanninkhof R. Relationship between wind speed and gas exchange over the ocean revisited. Limnol Oceanogr Methods, 2014, 12(6): 351-362.

[59]	Weiss R (1974) Carbon dioxide in water and seawater: the solubility of a non-ideal gas. Mar Chem 2(3):203–215.

[60]	Yang X, Xue L, Li Y, Han P, Liu X, Zhang L, Cai WJ (2018) Treated wastewater changes the export of dissolved inorganic carbon and its isotopic composition and leads to acidification in coastal oceans. Environ Sci Technol 52(10):5590–5599.

[61]	Yuan XC, Yin K, Cai WJ, Ho AY, Xu J, Harrison PJ. Influence of seasonal monsoons on net community production and CO₂ in subtropical Hong Kong coastal waters. Biogeosciences, 2011, 8: 289-300.