Modern Deposition Rates and Patterns of Carbon Burial in Southern Fiordland, New Zealand

Michael T Ramirez1, Mead A Allison2, Lael Vetter3, Xingqian Cui4, Thomas S Bianchi5, Richard Smith6, Candida Savage7 and Susanne Schüller7, (1)Tulane University of Louisiana, Earth and Environmental Sciences, New Orleans, LA, United States, (2)Tulane University of Louisiana, New Orleans, LA, United States, (3)Tulane University of Louisiana, Department of Earth and Environmental Sciences, New Orleans, LA, United States, (4)University of Florida, Department of Geological Sciences, Ft Walton Beach, FL, United States, (5)University of Florida, Geological Sciences, Ft Walton Beach, FL, United States, (6)Global Aquatic Research, Sodus, NY, United States, (7)University of Otago, Department of Marine Sciences, Dunedin, New Zealand
Abstract:
Fjords have been recognized as a hotspot of organic carbon burial, as they accumulate a disproportionate quantity of organic carbon given their areal extent in comparison to other marine settings. However, organic carbon is buried in context with other biogenic and mineral sediments, so localized sedimentation processes play a critical role in determining rates of organic carbon burial. Therefore, it is important to assess the local sources and processes responsible for depositing inorganic sediment as a control on the burial of organic carbon. Here we evaluate three fjords in southern New Zealand that are not glaciated, with a sedimentary system that is dominantly controlled by terrigenous input at fjord heads, reworking of sediments over fjord-mouth sills, and landslide events from the steep fjord walls. Sediment cores were collected throughout the three southernmost fjord systems of Fiordland, New Zealand, and analyzed to determine sedimentary fabric, mass accumulation rates, and organic carbon content. Sediment mass accumulation rates from 210Pb geochronology range up to 500 mg/cm2/yr in proximal and distal areas of the fjords, with lower rates (below 200 mg/cm2/yr) in medial reaches, where terrestrial and marine sediment input is minimal. X-radiographs and 210Pb downcore activity trends show evidence of both mass wasting and surface-sediment bioturbation operating throughout the fjords. Percent organic carbon displays a negative correlation with mass accumulation rate and thickness of the sediment surface mixed layer. Rates of organic carbon accumulation ranged from 3.97 to 21.59 mg/cm2/yr, with a mean of 13.41 mg/cm2/yr. Organic carbon accumulation rates are dependent on the sediment accumulation rate and the percent organic carbon of the sediment. Our results highlight the importance of spatial variability in sedimentation processes and rates within fjords when evaluating organic carbon burial in these systems.