Sustained high CO2 concentrations and fluxes from Australia’s largest river system
Sima Bargrizan A B , Tapas K. Biswas B , Klaus D. Joehnk B and Luke M. Mosley A *A School of Biological Sciences, University of Adelaide, Adelaide, SA 5001, Australia.
B CSIRO, Black Mountain, Canberra, ACT 2601, Australia.
Marine and Freshwater Research 73(4) 540-551 https://doi.org/10.1071/MF21154
Submitted: 28 May 2021 Accepted: 13 November 2021 Published: 8 February 2022
© 2022 The Author(s) (or their employer(s)). Published by CSIRO Publishing.
Abstract
Many of the world’s rivers have been found to be sources of CO2 to the atmosphere, however, there has been limited assessment in arid regions. This analysis of a long-term (1979–2013) dataset (n = 3496) along Australia’s largest river system (River Murray) showed that there were sustained high pCO2 (carbon dioxide partial pressure) levels, ranging from 1210 ± 107 to 3066 ± 579 µatm along the main river channel, and 5114 ± 1221 µatm on the major tributaries. As a consequence, the River Murray is a significant source of CO2 to the atmosphere, with an estimated average annual (±s.d.) flux of 218 ± 98 g C m−2 year−1 and total emissions of 355 000 ± 29 000 t CO2 year−1 over a total river area of 386 km2 from below Lake Hume to Tailem Bend, although there is some uncertainty with gas transfer coefficients. Supersaturation with CO2 relative to the atmosphere was maintained even under drought conditions with minimal external carbon inputs, suggesting internal carbon cycling and respiration is important in driving net CO2 production. Supersaturation of the river water relative to calcium carbonate minerals was also observed under low flow conditions. Hydro-climatic changes could be having significant impacts on the CO2 system in the River Murray and other arid river systems.
Keywords: alkalinity, calcium carbonate, carbon dioxide, climate change, gas exchange, heterotrophic respiration, Murray–Darling Basin, River Murray.
References
Aufdenkampe, AK, Maroga, E, Raymond, PA, Melack, JM, Domey, S, Alin, SR, Aalto, RE, and Yoo, K (2011). Riverine coupling of biogeochemical cycles between land, oceans, and atmosphere. Frontiers in Ecology and the Environment 9, 53–60.| Riverine coupling of biogeochemical cycles between land, oceans, and atmosphere.Crossref | GoogleScholarGoogle Scholar |
Bastviken, D, Tranvik, LJ, Downing, JA, Crill, PM, and Prast, LE (2011). Freshwater methane emissions offset the continental carbon sink. Science 331, 50.
| Freshwater methane emissions offset the continental carbon sink.Crossref | GoogleScholarGoogle Scholar | 21212349PubMed |
Beaulieu, E, Godderis, Y, Labat, D, Roelandt, C, Gaillartet, J, and Calmels, D (2011). Modeling of water-rock interaction in the Mackenzie basin: Competition between sulfuric and carbonic acids. Chemical Geology 289, 114–123.
| Modeling of water-rock interaction in the Mackenzie basin: Competition between sulfuric and carbonic acids.Crossref | GoogleScholarGoogle Scholar |
Biswas, TK, and Mosley, LM (2019). From mountain ranges to sweeping plains, in droughts and flooding rains; River Murray water quality over the last four decades. Water Resources Management 33, 1087–1101.
| From mountain ranges to sweeping plains, in droughts and flooding rains; River Murray water quality over the last four decades.Crossref | GoogleScholarGoogle Scholar |
Burt, TP, Howden, NJK, and Worrall, F (2014). On the importance of very long-term water quality records. Wiley Interdisciplinary Reviews: Water 1, 41–48.
| On the importance of very long-term water quality records.Crossref | GoogleScholarGoogle Scholar |
Cai, WJ, and Wang, Y (1998). The chemistry, fluxes and sources of carbon dioxide in the estuarine waters of the Satilla and Altamaha Rivers, Georgia. Limnology and Oceanography 43, 657–668.
| The chemistry, fluxes and sources of carbon dioxide in the estuarine waters of the Satilla and Altamaha Rivers, Georgia.Crossref | GoogleScholarGoogle Scholar |
Cai, WJ, Guo, XH, Chen, CTA, Dai, MH, Zhang, LJ, and Zhai, WD (2008). A comparative overview of weathering intensity and HCO3 S flux in the world’s major rivers with emphasis on the Changjiang, Huanghe, Zhujiang (Pearl) and Mississippi Rivers. Continental Shelf Research 28, 1538–1549.
| A comparative overview of weathering intensity and HCO3 S flux in the world’s major rivers with emphasis on the Changjiang, Huanghe, Zhujiang (Pearl) and Mississippi Rivers.Crossref | GoogleScholarGoogle Scholar |
Cole, JJ, and Caraco, NF (2001). Carbon in catchments: connecting terrestrial carbon losses with aquatic metabolism. Marine and Freshwater Research 52, 101–110.
| Carbon in catchments: connecting terrestrial carbon losses with aquatic metabolism.Crossref | GoogleScholarGoogle Scholar |
Cole, JJ, Prairie, YT, Caraco, NF, McDowell, WH, Tranvik, LJ, and Striegl, RG (2007). Plumbing the global carbon cycle: Integrating inland waters into the terrestrial carbon budget. Ecosystems 10, 171–184.
| Plumbing the global carbon cycle: Integrating inland waters into the terrestrial carbon budget.Crossref | GoogleScholarGoogle Scholar |
Doney, SC, Fabry, VJ, Feely, RA, and Kleypas, JA (2009). Ocean acidification: the other CO2 problem. Annual Review of Marine Science 1, 169–192.
| Ocean acidification: the other CO2 problem.Crossref | GoogleScholarGoogle Scholar | 21141034PubMed |
Drupp, P, Carlo, EHD, Mackenzie, FT, Bienfang, P, and Sabine, CL (2011). Nutrient inputs, phytoplankton response, CO2 variations in a semi-enclosed subtropical embayment, Kaneohe Bay, Hawaii. Aquatic Geochemistry 17, 473–498.
| Nutrient inputs, phytoplankton response, CO2 variations in a semi-enclosed subtropical embayment, Kaneohe Bay, Hawaii.Crossref | GoogleScholarGoogle Scholar |
Dubois, KD, Lee, D, and Veizer, J (2010). Isotopic constraints on alkalinity, dissolved organic carbon, and atmospheric carbon dioxide fluxes in the Mississippi River. Journal of Geophysical Research 115, G02018.
| Isotopic constraints on alkalinity, dissolved organic carbon, and atmospheric carbon dioxide fluxes in the Mississippi River.Crossref | GoogleScholarGoogle Scholar |
Hart BT, Davidson D (2017) ‘The Murray–Darling basin plan: decision making in water resources policy, planning and management: the Australian perspective’. (Eds BT Hart, J Doolan) pp. 221–244. (Elsevier Publishing: New York, NY)
Howden, NJK, Burt, TP, Worrall, F, Whelan, MJ, and Bieroza, M (2010). Nitrate concentrations and fluxes in the river thames over 140 years (1868–2008): are increases irreversible? Hydrological Process 23, 2657–2662.
| Nitrate concentrations and fluxes in the river thames over 140 years (1868–2008): are increases irreversible?Crossref | GoogleScholarGoogle Scholar |
Hunt, CW, Salisbury, JE, and Vandemark, D (2011). Contribution of non-carbonate anions to total alkalinity and overestimation of pCO2 in New England and New Brunswick rivers. Biogeosciences 8, 3069–3076.
| Contribution of non-carbonate anions to total alkalinity and overestimation of pCO2 in New England and New Brunswick rivers.Crossref | GoogleScholarGoogle Scholar |
Kaushal, SS, Groffman, PM, Band, LE, Shields, CA, Morgan, RP, Palmer, MA, Belt, KT, Swan, CM, Findlay, SEG, and Fisher, GT (2008). Interaction between urbanization and climate variability amplifies watershed nitrate export in Maryland. Environmental Science and Technology 42, 5872–5878.
| Interaction between urbanization and climate variability amplifies watershed nitrate export in Maryland.Crossref | GoogleScholarGoogle Scholar | 18767638PubMed |
Kaushal, SS, Delaney-Newcomb, K, Findlay, SEG, Newcomer, TA, Duan, S, Pennino, MJ, Sivirichi, GM, Sides-Rely, AM, Walbridge, MR, and Belt, KT (2014). Longitudinal changes in carbon and nitrogen fluxes and stream metabolism along an urban watershed continuum. Biogeochemistry 121, 1–22.
| Longitudinal changes in carbon and nitrogen fluxes and stream metabolism along an urban watershed continuum.Crossref | GoogleScholarGoogle Scholar |
Li, SY, Lu, XX, and Bush, RT (2013). CO2 partial pressure and CO2 emission in the Lower Mekong River. Journal of Hydrology 504, 40–56.
| CO2 partial pressure and CO2 emission in the Lower Mekong River.Crossref | GoogleScholarGoogle Scholar |
Mackay N, Hillman T, Rolls J (1988) Water quality of the River Murray: review of monitoring 1978–1986. (Water Quality Report No. 1).
MDBA (2010) Guide to the proposed basin plan: technical background, Murray–Darling Basin authority. Available at http://www.mdba.gov.au/kid/guide/
MDBA (2017) Towards a healthy, working Murray–Darling basin: Basin Plan annual report. pp. 2015–2016. Publication No. 40/17, Murray–Darling Basin Authority, Canberra.
Mosley, LM, and Fleming, N (2010). Pollutant loads returned to the lower Murray River from flood-irrigated agriculture. Water Air and Soil Pollution 211, 475–487.
| Pollutant loads returned to the lower Murray River from flood-irrigated agriculture.Crossref | GoogleScholarGoogle Scholar |
Mosley, L, and Liss, P (2020). Particle aggregation, pH changes and metal behaviour during estuarine mixing: review and integration. Marine and Freshwater Research 71, 300–310.
| Particle aggregation, pH changes and metal behaviour during estuarine mixing: review and integration.Crossref | GoogleScholarGoogle Scholar |
Mosley, LM, Daly, R, Palmer, D, Yeates, P, Dallimore, C, Biswas, T, and Simpson, SL (2015). Predictive modelling of pH and dissolved metal concentrations and speciation following mixing of acid drainage with river water. Applied Geochemistry 59, 1–10.
| Predictive modelling of pH and dissolved metal concentrations and speciation following mixing of acid drainage with river water.Crossref | GoogleScholarGoogle Scholar |
Mosley, LM, Wallace, T, Rahman, J, Roberts, T, and Gibbs, M (2021). An integrated model to predict and prevent hypoxia in floodplain-river systems. Journal of Environmental Management 286, 112213.
| An integrated model to predict and prevent hypoxia in floodplain-river systems.Crossref | GoogleScholarGoogle Scholar | 33684798PubMed |
Nydahl, AC, Wallin, MB, and Weyhenmeyer, GA (2017). No long-term trends in pCO2 despite increasing organic carbon concentrations in boreal lakes, streams, and rivers. Global Biogeochemical Cycles 31, 985–995.
| No long-term trends in pCO2 despite increasing organic carbon concentrations in boreal lakes, streams, and rivers.Crossref | GoogleScholarGoogle Scholar |
Oliver RL, Lorenz Z (2013) Flood plain influences on metabolic activity in the South Australian section of the Murray River during the 2010/11 flood. Goyder Institute for Water Research, Technical Report Series No. 13/1.
Parkhurst DL, Appelo CAJ (1999) A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations. Water-Resources Investigations Report. pp. 99–4259.
Raymond, PA, and Cole, JJ (2001). Gas exchange in rivers and estuaries: choosing a gas transfer velocity. Estuaries 24, 312–317.
| Gas exchange in rivers and estuaries: choosing a gas transfer velocity.Crossref | GoogleScholarGoogle Scholar |
Raymond, PA, and Cole, JJ (2003). Increase in the export of alkalinity from North America’s largest river. Science 301, 88–91.
| Increase in the export of alkalinity from North America’s largest river.Crossref | GoogleScholarGoogle Scholar | 12843391PubMed |
Raymond, PA, Caraco, NF, and Cole, JJ (1997). Carbon dioxide concentration and atmospheric flux in the Hudson River. Estuaries 20, 381–390.
| Carbon dioxide concentration and atmospheric flux in the Hudson River.Crossref | GoogleScholarGoogle Scholar |
Raymond, PA, Hartmann, J, Lauerwald, R, Sobek, S, McDonald, C, Hoover, M, Butman, D, Striegl, R, Mayorga, E, Humborg, C, Kortelainen, P, Durr, H, Meybeck, M, Ciais, P, and Guth, P (2013). Global carbon dioxide emissions from inland waters. Nature 503, 355–359.
| Global carbon dioxide emissions from inland waters.Crossref | GoogleScholarGoogle Scholar | 24256802PubMed |
Richey, JE, Melack, JM, Aufdenkampe, AK, Ballester, VM, and Hess, LL (2002). Outgassing from Amazonian rivers and wetlands as a large tropical source of atmospheric CO2. Nature 416, 617–620.
| Outgassing from Amazonian rivers and wetlands as a large tropical source of atmospheric CO2.Crossref | GoogleScholarGoogle Scholar | 11948346PubMed |
Sander, R (2015). Compilation of Henry’s law constants (version 4.0) for water as solvent. Atmospheric Chemistry and Physics 15, 4399–4981.
| Compilation of Henry’s law constants (version 4.0) for water as solvent.Crossref | GoogleScholarGoogle Scholar |
Shanley, JB, Kendall, C, Smith, TE, Wolock, DM, and McDonnell, JJ (2002). Controls on old and new water contributions to stream flow at some nested catchments in Vermont, USA. Hydrological Processes 16, 589–609.
| Controls on old and new water contributions to stream flow at some nested catchments in Vermont, USA.Crossref | GoogleScholarGoogle Scholar |
Shen, C, Testa, JM, Li, M, Cai, WJ, Waldbusser, GG, Ni, W, Kemp, WM, Cornwell, J, Chen, B, Brodeur, J, and Su, J (2018). Controls on carbonate system dynamics in a coastal plain estuary: a modelling study. Journal of Geophysical Research Biogeoscience 124, 61–78.
| Controls on carbonate system dynamics in a coastal plain estuary: a modelling study.Crossref | GoogleScholarGoogle Scholar |
Striegl, RG, Dornblaser, MM, McDonald, CP, Rover, JR, and Stets, EG (2012). Carbon dioxide and methane emissions from the Yukon River system. Global Biogeochemical Cycles 26, GB0E05.
| Carbon dioxide and methane emissions from the Yukon River system.Crossref | GoogleScholarGoogle Scholar |
Stumm W, Morgan J (1996) ‘Aquatic chemistry: chemical equilibria and rates in natural waters’, 3rd edn. (Wiley-Interscience: New York, NY)
Teodoru, CR, Giorgio, P A, Prairie, YT, and Martine, C (2009). Patterns in pCO2 in boreal streams and rivers of northern Quebec, Canada. Global Biogeochemical Cycles 23, GB2012.
| Patterns in pCO2 in boreal streams and rivers of northern Quebec, Canada.Crossref | GoogleScholarGoogle Scholar |
Tranvik, LJ, Downing, JA, Cotner, JB, Loiselle, SA, Striegl, RG, Ballatore, TJ, Dillon, P, Finlay, K, Fortino, K, Knoll, LB, Kortelainen, DL, Kutse, T, Larsen, S, Laurion, L, Leech, DM, McCallister, S,L, McKnight, DM, Melack, JM, Overholt, E, Porter, JA, Prairie, Y, Renwick, WH, Ronald, F, Sherman, BS, Schindler, DW, Sobek, S, Tremblay, A, Vanni, MJ, Verschoor, AM, Wachenfeldt, EV, and Weyhenmeyer, GA (2009). Lakes and reservoirs as regulators of carbon cycling and climate. Limnology Oceanography 54, 2298–314.
| Lakes and reservoirs as regulators of carbon cycling and climate.Crossref | GoogleScholarGoogle Scholar |
Wallace, TA, and Furst, D (2016). Open water metabolism and dissolved organic carbon in response to environmental watering in a lowland river–floodplain complex. Marine Freshwater Research 67, 1346–1361.
| Open water metabolism and dissolved organic carbon in response to environmental watering in a lowland river–floodplain complex.Crossref | GoogleScholarGoogle Scholar |
Wang, FS, Wang, YC, Zhang, J, Xu, H, and Wei, XG (2007). Human impact on the historical change of CO2 degassing flux in river changjiang. Geochemical Transactions 8, 7.
| Human impact on the historical change of CO2 degassing flux in river changjiang.Crossref | GoogleScholarGoogle Scholar |
Wang, X, He, Y, Yuan, X, Chen, H, Peng, C, Zhu, Q, Yue, J, Ren, H, Deng, W, and Liu, H (2017). pCO2 and CO2 fluxes of the metropolitan river network in relation to the urbanization of Chongqing, China. Journal of Geophysical Research: Biogeosciences 122, 470–286.
| pCO2 and CO2 fluxes of the metropolitan river network in relation to the urbanization of Chongqing, China.Crossref | GoogleScholarGoogle Scholar |
Wanninkhof, R (1992). Relationship between wind-speed and gas exchange over the ocean. Journal of Geophysical Research 97, 7373–7382.
| Relationship between wind-speed and gas exchange over the ocean.Crossref | GoogleScholarGoogle Scholar |
Yao, G, Gao, Q, Wang, Z, Huang, X, He, T, Zhang, Y, Jiao, S, and Ding, J (2007). Dynamics of CO2 partial pressure and CO2 outgassing in the lower reaches of the Xijiang river, a subtropical monsoon river in China. Science of the Total Environment 376, 255–266.
| Dynamics of CO2 partial pressure and CO2 outgassing in the lower reaches of the Xijiang river, a subtropical monsoon river in China.Crossref | GoogleScholarGoogle Scholar |