FN Archimer Export Format
PT J
TI Benthic Foraminifera in Arctic Methane Hydrate Bearing Sediments
BT 
AF DESSANDIER, Pierre-Antoine
   BORRELLI, Chiara
   KALENITCHENKO, Dimitri
   PANIERI, Giuliana
AS 1:1;2:2;3:1;4:1;
FF 1:;2:;3:;4:;
C1 UiT Arctic Univ Norway, Dept Geosci, Ctr Arctic Gas Hydrate Environm & Climate, Tromso, Norway.
   Univ Rochester, Dept Earth & Environm Sci, Rochester, NY USA.
C2 UNIV TROMSO, NORWAY
   UNIV ROCHESTER, USA
IN DOAJ
TC 17
UR https://archimer.ifremer.fr/doc/00667/77894/80079.pdf
   https://archimer.ifremer.fr/doc/00667/77894/80080.xlsx
LA English
DT Article
DE ;benthic foraminiferal assemblages;methane advection;methane diffusion;Arctic Ocean;microbial mats
AB Benthic foraminifera have been widely used as proxy for paleo-methane emissions, mainly based on their stable isotopic signature. In cold seeps, the ecology of these organisms remains uncertain, in particular their ability to thrive during active phases of seepage. In this study, we evaluate the benthic foraminiferal response to methane seepage in Arctic sediments. We do so by examining living and dead benthic foraminiferal assemblages (>63 mu m) of 11 push cores collected in two of the most active pockmarks (Lunde and Lomvi) along Vestnesa Ridge, offshore western Svalbard. Benthic foraminiferal assemblages are interpreted in the context of sediment geochemistry, seafloor images, and pore water analyses, which are used to characterize the different microhabitats. At the sampling locations, methane is currently being released making these the ideal sites to investigate the connection between the benthic foraminiferal distribution and methane seepage in the Arctic Ocean. Our results show that benthic calcareous foraminifera live in methane charged sediments, even if the faunal density and diversity is low. We note that the eutrophic-tolerant species Melonis barleeanus withstand the methane-induced hostile geochemical conditions and that it seems to prosper on the additional food availability represented by microbial mats growing at methane seeps. We also observe that the methane transport mechanisms affect different species differently. For example, sediments characterized by advective-like conditions are distinguished by a high density of living individuals, dominated by Cassidulina neoteretis, whereas sediments characterized by methane diffusion exhibit a very low faunal density. Agglutinated foraminifera are less abundant in sediments influenced by methane seepage, suggesting that this group of foraminifera does not tolerate the geochemical conditions at seeps. A comparison between the size fractions >63 and >125 mu m highlights the importance of studying the finer size fraction for ecological studies in the Arctic Ocean. In the light of our results, we conclude that benthic foraminiferal can thrive at active methane seeps, where assemblages are clearly affected by methane flux.
PY 2019
PD DEC
SO Frontiers In Marine Science
PU Frontiers Media Sa
VL 6
UT 000502968200001
DI 10.3389/fmars.2019.00765
ID 77894
ER

EF