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High-concentration sediment plumes, Horseshoe Island, western Antarctic Peninsula

Published online by Cambridge University Press:  24 March 2021

Cristian Rodrigo Open the ORCID record for Cristian Rodrigo [Opens in a new window] ,
Andrés Varas-Gómez ,
Adrián Bustamante-Maino  and
Emilio Mena-Hodges
Cristian Rodrigo*
Affiliation:
Facultad de Ingenieria-Geologia, Universidad Andres Bello, Quillota 980, Viña del Mar, Chile
Andrés Varas-Gómez
Affiliation:
Departamento de Oceanografia y Medio Ambiente, Instituto de Fomento Pesquero, Manuel Blanco Encalada 839, Valparaiso, Chile
Adrián Bustamante-Maino
Affiliation:
Departamento de Oceanografia y Medio Ambiente, Instituto de Fomento Pesquero, Manuel Blanco Encalada 839, Valparaiso, Chile
Emilio Mena-Hodges
Affiliation:
Facultad de Ciencias Quimicas, Universidad de Concepcion, Victor Lamas 1290, Concepcion, Chile
*
cristian.rodrigo@unab.cl
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Extract

The variability in sediment concentration and spatial distribution of meltwater discharges from tidewater glaciers can be used to elucidate climatic evolution and glacier behaviour due to the association between sediment yield and glacier retreat (e.g. Domack & McClennen 1996). In an accelerated deglaciation environment, higher sediment concentrations in the water column can change the glacimarine costal dynamics and affect productivity and sea floor ecosystems (e.g. Marín et al. 2013). In the Antarctic Peninsula Region, meltwater or turbid plumes were previously believed to be rare or without an important role in the sedimentary glacimarine environment (e.g. Griffith & Anderson 1989), but recent studies have shown that this is a common phenomenon in subpolar and transition polar climates (Yoo et al. 2015, Rodrigo et al. 2016). In the current climate change scenario, accelerated glacier retreats and mass losses can produce an increasing input of glacial meltwater into the fjord regions, a situation that is not yet well evaluated in the Antarctic Peninsula. In this short note, after in situ observation of an unusual waterfall from the southern side of the main western tidewater glacier (Shoesmith Glacier) of Horseshoe Island (Lystad Bay), Marguerite Bay (Fig. 1), we report high turbidity values associated with plumes from the glacier, whose values were higher than reported data from subpolar/transition polar Antarctic climates.

Keywords

climate changeglacimarine environmentsoceanographic variablestidewater glacierturbidity
Type
Physical Sciences
Information
Antarctic Science , Volume 33 , Issue 2 , April 2021 , pp. 213 - 216
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Copyright
Copyright © Antarctic Science Ltd 2021

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References

Antezana, T. 1999. Hydrographic features of Magellan and Fuegian inland passages and adjacent Subantarctic waters. Scientia Marina, 63(Suppl. 1), 2334.CrossRefGoogle Scholar
Castilla-Hidalgo, G., Landaeta, M., Anaya-Godinez, E. & Bustos, C. 2018. Larval fish assemblages from channels and fjords of south Pacific Patagonia: effects of environmental conditions. Revista de Biología Marina y Oceanografía, 53, 3949.CrossRefGoogle Scholar
Cook, A.J., Vaughan, D.G., Luckman, A.J. & Murray, T. 2014. A new Antarctic Peninsula glacier basin inventory and observed area changes since the 1940s. Antarctic Science, 26, 614624.CrossRefGoogle Scholar
Cook, A.J., Holland, P.R., Meredith, M.P., Murray, T., Luckman, A. & Vaughan, D.G. 2016. Ocean forcing of glacier retreat in the western Antarctic Peninsula. Science, 15, 283286.CrossRefGoogle Scholar
Domack, E.W. & McClennen, C.E. 1996. Accumulation of glacial marine sediments in fjords of the Antarctic Peninsula and their use as Late Holocene paleoenvironmental indicators. Antarctic Research Series, 70, 135154.CrossRefGoogle Scholar
Griffith, T.W. & Anderson, J. 1989. Climatic control of sedimentation in bays and fjords of the northern Antarctic Peninsula. Marine Geology, 85, 181284.CrossRefGoogle Scholar
Marín, V., Tironi, A., Paredes, M.A. & Contreras, M. 2013. Modeling suspended solids in a northern Chilean Patagonia glacier-fed fjord: GLOF scenarios under climate change conditions. Ecological Modelling, 264, 716.CrossRefGoogle Scholar
Rodrigo, C., Giglio, S. & Varas, A., 2016. Glacier sediment plumes in small bays on the Danco Coast, Antarctic Peninsula. Antarctic Science, 28, 395404.CrossRefGoogle Scholar
Yoo, K., Kyung Lee, M., Il Yoon, H., Il Lee, Y. & Yoon Kang, C. 2015. Hydrography of Marian Cove, King George Island, West Antarctica: implications for ice-proximal sedimentation during summer. Antarctic Science, 27, 185196.CrossRefGoogle Scholar