FN Archimer Export Format
PT J
TI A RUpture‐Based detection method for the Active mesopeLagIc Zone (RUBALIZ): A crucial step toward rigorous carbon budget assessments
BT 
AF Fuchs, Robin
   Baumas, Chloé M. J.
   Garel, Marc
   Nerini, David
   Le Moigne, Frédéric A. C.
   Tamburini, Christian
AS 1:1,2;2:1;3:1;4:1;5:3;6:1;
FF 1:;2:;3:;4:;5:;6:;
C1 Aix Marseille Univ Université de Toulon, CNRS, IRD, MIO UM 110 Marseille, France
   Aix Marseille Univ, CNRS, I2M Marseille , France
   LEMAR Laboratoire des Sciences de l’Environnement Marin, UMR6539 CNRS, UBO, IFREMER, IRD Plouzané Technopôle Brest‐Iroise , France
C2 UNIV AIX MARSEILLE, FRANCE
   UNIV AIX MARSEILLE, FRANCE
   CNRS, FRANCE
UM LEMAR
IN WOS Cotutelle UMR
   copubli-france
IF 2.7
TC 3
UR https://archimer.ifremer.fr/doc/00800/91226/96976.pdf
   https://archimer.ifremer.fr/doc/00800/91226/96977.docx
LA English
DT Article
CR PEACETIME
   TONGA 2019
BO Pourquoi pas ?
   L'Atalante
AB Determining mesopelagic organic carbon budgets is essential to characterize the ocean's role as a carbon dioxide sink. This is because the biological processes observed in the mesopelagic zone are crucial for understanding the biological carbon pump. Yet, field assessments of carbon budgets are often unbalanced with the carbon demand exceeding its supply. This underlines either methodological issues in the budget calculations or incomplete knowledge of the mesopelagic carbon cycling with potentially missing sources. Carbon budgets are built by partitioning the ocean into vertical depth zones. Vertical boundaries are conventionally defined between 200 and 1000 m depth or using various thresholds. Such approaches lack consistent methodology preventing robust comparison of mesopelagic carbon budget from region to region. Here, using a statistical rupture detection method applied to conductivity–temperature–depth (CTD)-cast variables (fluorescence, O2 concentration, potential temperature, salinity, and density), we aim to provide independent estimates of mesopelagic boundaries. We demonstrate that the so-determined upper boundary is highly correlated with the knee points of the particulate organic carbon (POC) fluxes estimated by a power law and that over 90% of the POC flux attenuation occurs within our method boundaries. The identified zone therefore corresponds to the most active part of the conventional mesopelagic zone and we name it the “active mesopelagic zone” (AMZ). We find that the depths of the mesopelagic zone depend on the region considered. Our results demonstrate that the mesopelagic carbon budget discrepancy can vary up to four folds depending on the boundaries chosen and hence provide novel grounds to reassess existing and future mesopelagic carbon budgets. 
PY 2023
PD JAN
SO Limnology And Oceanography-methods
SN 1541-5856
PU Wiley
VL 21
IS 1
UT 000874514400001
BP 24
EP 39
DI 10.1002/lom3.10520
ID 91226
ER

EF