Organic carbon mass accumulation rate regulates the flux of reduced substances from the sediments of deep lakes

Abstract. The flux of reduced substances, such as methane and ammonium, from the sediment to the bottom water (Fred) is one of the major factors contributing to the consumption of oxygen in the hypolimnia of lakes and thus crucial for lake oxygen management. This study presents fluxes based on sediment porewater measurements from different water depths of five deep lakes of differing trophic states. In meso- to eutrophic lakes Fred was directly proportional to the total organic carbon mass accumulation rate (TOC-MAR) of the sediments. TOC-MAR and thus Fred in eutrophic lakes decreased systematically with increasing mean hypolimnion depth (zH), suggesting that high oxygen concentrations in the deep waters of lakes were essential for the extent of organic matter mineralization leaving a smaller fraction for anaerobic degradation and thus formation of reduced compounds. Consequently, Fred was low in the 310 m deep meso-eutrophic Lake Geneva, with high O2 concentrations in the hypolimnion. By contrast, seasonal anoxic conditions enhanced Fred in the deep basin of oligotrophic Lake Aegeri. As TOC-MAR and zH are based on more readily available data, these relationships allow estimating the areal O2 consumption rate by reduced compounds from the sediments where no direct flux measurements are available.

[1]  A. Wüest,et al.  Using small‐scale measurements to estimate hypolimnetic oxygen depletion in a deep lake , 2018 .

[2]  N. Anderson,et al.  The historical dependency of organic carbon burial efficiency , 2017 .

[3]  A. Wüest,et al.  Effects of climate change on deepwater oxygen and winter mixing in a deep lake (Lake Geneva): Comparing observational findings and modeling , 2016 .

[4]  B. Wehrli,et al.  Mineralization pathways of organic matter deposited in a river-lake transition of the Rhone River Delta, Lake Geneva. , 2015, Environmental science. Processes & impacts.

[5]  P. Hauser,et al.  Sediment porewater extraction and analysis combining filter tube samplers and capillary electrophoresis. , 2013, Environmental science. Processes & impacts.

[6]  C. Schubert,et al.  Anaerobic oxidation of methane in an iron‐rich Danish freshwater lake sediment , 2013 .

[7]  S. Mangold,et al.  New insights into the formation and burial of Fe/Mn accumulations in Lake Baikal sediments , 2012 .

[8]  Donald E. Canfield,et al.  Carbon mineralization and oxygen dynamics in sediments with deep oxygen penetration, Lake Superior , 2012 .

[9]  Andreas Matzinger,et al.  Hypolimnetic oxygen depletion in eutrophic lakes. , 2012, Environmental science & technology.

[10]  A. Lotter,et al.  Impact of recent lake eutrophication on microbial community changes as revealed by high resolution lipid biomarkers in Rotsee (Switzerland) , 2012 .

[11]  Andreas Matzinger,et al.  Hypolimnetic oxygen consumption by sediment‐based reduced substances in former eutrophic lakes , 2010 .

[12]  Martin Wessels,et al.  Organic carbon burial efficiency in lake sediments controlled by oxygen exposure time and sediment source , 2009 .

[13]  Beat Müller,et al.  Mineralization pathways in lake sediments with different oxygen and organic carbon supply , 2009 .

[14]  Beat Müller,et al.  Microscale mineralization pathways in surface sediments: A chemical sensor study in Lake Baikal , 2006 .

[15]  David A. Matthews,et al.  Long‐term changes in the areal hypolimnetic oxygen deficit (AHOD) of Onondaga Lake: Evidence of sediment feedback , 2006 .

[16]  B. Wehrli,et al.  Influence of organic carbon decomposition on calcite dissolution in surficial sediments of a freshwater lake. , 2003, Water research.

[17]  B. Wehrli,et al.  Sedimentary profiles of Fe, Mn, V, Cr, As and Mo as indicators of benthic redox conditions in Baldeggersee , 1997, Aquatic Sciences.

[18]  E. Epping,et al.  Oxygen budgets calculated fromin situ oxygen microprofiles for Northern Adriatic sediments , 1997 .

[19]  B. Wehrli,et al.  Solute transfer across the sediment surface of a eutrophic lake: I. Porewater profiles from dialysis samplers , 1997, Aquatic Sciences.

[20]  Dieter M. Imboden,et al.  The prediction of hypolimnetic oxygen profiles: a plea for a deductive approach , 1996 .

[21]  Karline Soetaert,et al.  A model of early diagenetic processes from the shelf to abyssal depths , 1996 .

[22]  P. Brezonik,et al.  Sediment pore-water dynamics of Little Rock Lake, Wisconsin : geochemical processes and seasonal and spatial variability , 1994 .

[23]  R. Carignan,et al.  Use of diffusion samplers in oligotrophic lake sediments: Effects of free oxygen in sampler material , 1994 .

[24]  K. Martens,et al.  Oxygen concentration profiles in soft sediment of Lake Baikal (Russia) near the Selenga delta , 1993 .

[25]  R. Carignan,et al.  Regeneration of dissolved substances in a seasonally anoxic lake: The relative importance of processes occurring in the water column and in the sediments , 1991 .

[26]  D. Arbouille,et al.  Variation of nutrient stocks in the superficial sediments of Lake Geneva from 1978 to 1988 , 1990, Hydrobiologia.

[27]  Dominic M. DiToro,et al.  Sediment Oxygen Demand Model: Methane and Ammonia Oxidation , 1990 .

[28]  R. Conrad,et al.  Oxidation of methane in the oxic surface layer of a deep lake sediment (Lake Constance) , 1990 .

[29]  U. Uehlinger,et al.  Horizontal sedimentation differences in a eutrophic Swiss lake , 1986 .

[30]  J. Dominik,et al.  Texture and sedimentation rates in Lake Geneva , 1983 .

[31]  D. D. Adams,et al.  Flux of reduced chemical constituents (Fe2+, Mn2+, NHinf4sup+ and CH4) and sediment oxygen demand in Lake Erie , 1982, Hydrobiologia.

[32]  F. Rigler,et al.  Hypolinimetic Oxygen Deficits: Their Prediction and Interpretation , 1979, Science.

[33]  J. T. Lehman Reconstructing the Rate of Accumulation of Lake Sediment: The Effect of Sediment Focusing , 1975, Quaternary Research.

[34]  Jean-Luc Loizeau,et al.  Taux d'accumulation de sédiments récents et bilan de la matière particulaire dans le Léman (Suisse - France) , 2012 .

[35]  Alfred Wüest,et al.  Entwicklung des Phosphorhaushalts und der Sauerstoffzehrung im Sempacher- und Baldeggersee , 2012 .

[36]  G. Matisoff,et al.  Sediment Oxygen Demand in the Central Basin of Lake Erie , 2008 .

[37]  J. McManus,et al.  Carbon and Nutrient Cycling at the Sediment-water Boundary in Western Lake Superior , 2004 .

[38]  B. Wehrli,et al.  Geochemical-focusing of manganese in lake sediments — An indicator of deep-water oxygen conditions , 1996 .

[39]  P. Anderson,et al.  Variations in Sediment Accumulation Rates and the Flux of Labile Organic Matter in Eastern Lake Superior Basins , 1989 .

[40]  K. Nealson,et al.  Distributions of Manganese, Iron, and Manganese-Oxidizing Bacteria In Lake Superior Sediments of Different Organic Carbon Content , 1989 .

[41]  M. Lidstrom,et al.  Methane Oxidation in Lake Superior Sediments , 1989 .

[42]  J. J. Morgan,et al.  Aquatic Chemistry: Chemical Equilibria and Rates in Natural Waters , 1970 .

[43]  G. E. Hutchinson,et al.  On the Relation between the Oxygen Deficit and the productivity and Typology of Lakes , 1938 .

[44]  J. Fisher,et al.  Early Diagenesis And Chemical Mass Transfer In Lake Erie Sediments , 1900 .