Skip to main content
Publications | Persons | Institutes | Projects
[ report an error in this record ]basket (0): add | show Print this page

Giant saltwater inflow in AD 1951 triggered Baltic Sea hypoxia
Moros, M.; Kotilainen, A.T.; Snowball, I.; Neumann, T.; Perner, Kerstin; Meier, H.E.M.; Papenmeier, S.; Kolling, H.; Leipe, T.; Sinninghe Damsté, J.S.; Schneider, R. (2024). Giant saltwater inflow in AD 1951 triggered Baltic Sea hypoxia. Boreas 53(2): 125-138. https://dx.doi.org/10.1111/bor.12643
In: Boreas. Scandinavian University Press/Wiley-Blackwell: Oslo. ISSN 0300-9483; e-ISSN 1502-3885, more
Peer reviewed article  

Available in  Authors 

Authors  Top 
  • Moros, M.
  • Kotilainen, A.T.
  • Snowball, I.
  • Neumann, T.
  • Perner, K.
  • Meier, H.E.M.
  • Papenmeier, S.
  • Kolling, H.
  • Leipe, T.
  • Sinninghe Damsté, J.S., more
  • Schneider, R.

Abstract
    A marked sedimentological change in subsurface sediments from the entire Baltic Proper, the Baltic Sea, has been previously noted. Our detailed work on a variety of multi-cores from basin-wide transects indicates that this sedimentological change was caused by a large shift in environmental conditions during the 1950s. Until the 1950s, the water column was rather weakly stratified and winter-time convection – although weakened during the post Little Ice Age warming – was still able to ventilate the bottom waters of the Baltic Proper. Therefore, complete sediment sequences only accumulated in calm waters deeper than 150–160 m. High-resolution benthic foraminiferal records of subsurface sediments obtained along the saline water inflow pathway in combination with historical data indicate that the depositional environment changed drastically owing to the giant saline water inflow in AD 1951. The accompanied sharpening of the halo(pycno)cline triggered a collapse in the ventilation of the basin, resulting in oxygen-deficient bottom waters. This deficiency, in turn, caused the onset of phosphate release from the sediments, which accelerated primary production. The ventilation collapse also enabled the onset of deposition of organic carbon-rich sediments also in shallower water areas as calm conditions prevailed up to the modern winter mixing depth (60–70 m). A slight return to Little Ice Age-type conditions was observed during the late 1980s when temperatures decreased and stratification weakened. These conditions gave rise to a reduction in hypoxic areas and to a bottom-water ventilation, most pronounced in the north of the so-called Baltic Sea Klint, a hydrographic and topographic barrier. However, the general environmental conditions essentially have not changed since the 1950s. Remarkably, external (temperature and stratification) in combination with internal factors (e.g. ventilation collapse and phosphate release) were able to change the redox conditions of the Baltic Proper from oxic to hypoxic within less than 10 years.

All data in the Integrated Marine Information System (IMIS) is subject to the VLIZ privacy policy Top | Authors