Sensitivity of the tropical dust cycle to glacial abrupt climate changes

Peter Hopcroft*, Sylvain Pichat, Paul J. Valdes, Stephanie Kienast

*Corresponding author for this work

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Abstract

During abrupt climate changes of the last glacial period paleorecords show large amplitude changes in the dust cycle. We use Earth System model simulations to evaluate processes operating across these events. Idealized Heinrich stadial‐like simulations show a southwards migration of tropical rainfall that dries the Sahel and reduces wet deposition causing a widespread enhancement of tropical dust loading. However, several discrepancies with marine core dust deposition reconstructions are evident. Simulations with a more limited freshwater forcing (0.4 Sv instead of 1.0 Sv) and weaker cooling over the North Atlantic (less than 3°C) show a switch in sign of the stadial dust deposition anomaly in several regions, improving agreement with paleorecords. The simulated dust cycle therefore displays in places a non‐linear response to abrupt change. The global‐mean stadial dust radiative forcing in the more realistic simulations is around −0.2 to −0.6 W m−2 and so could represent an amplifying feedback during these events.
Original languageEnglish
Article numbere2022GL101197
JournalGeophysical Research Letters
Volume50
Issue number1
Early online date24 Dec 2022
DOIs
Publication statusPublished - 16 Jan 2023

Keywords

  • Mineral dust
  • ESM
  • Stadial
  • Abrupt climate change
  • Paleodust
  • Glacial
  • Climatology
  • Climate
  • Regional climate change
  • Marine pollution
  • Global climate models
  • Air/sea constituent fluxes
  • Air/sea interactions
  • OCEANOGRAPHY: BIOLOGICAL AND CHEMICAL
  • Volcano/climate interactions
  • Research Letter
  • Mass balance
  • Explosive volcanism
  • mineral dust
  • Volcanic effects
  • Theoretical modeling
  • Volcanic hazards and risks
  • Aerosols and particles
  • Surface waves and tides
  • HYDROLOGY
  • Numerical modeling
  • BIOGEOSCIENCES
  • Atmospheric effects
  • Oceans
  • Mud volcanism
  • Gravity and isostasy
  • Climate impact
  • Avalanches
  • GEODESY AND GRAVITY
  • NATURAL HAZARDS
  • General circulation
  • SEISMOLOGY
  • Climate dynamics
  • Volcano monitoring
  • Land/atmosphere interactions
  • Water cycles
  • Global change from geodesy
  • Benefit‐cost analysis
  • INFORMATICS
  • Aerosols
  • PALEOCEANOGRAPHY
  • OCEANOGRAPHY: PHYSICAL
  • paleodust
  • Oceanic
  • Impacts of global change
  • Radio oceanography
  • Physical modeling
  • Risk
  • Urban systems
  • GLOBAL CHANGE
  • Disaster risk analysis and assessment
  • Modeling
  • VOLCANOLOGY
  • Atmospheric
  • Geological
  • Ocean/atmosphere interactions
  • Climate change and variability
  • Climate variability
  • Numerical solutions
  • Hydrological cycles and budgets
  • Earth system modeling
  • RADIO SCIENCE
  • Decadal ocean variability
  • Tsunamis and storm surges
  • abrupt climate change
  • MARINE GEOLOGY AND GEOPHYSICS
  • glacial
  • ATMOSPHERIC PROCESSES
  • Effusive volcanism
  • Ocean monitoring with geodetic techniques
  • Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions
  • Megacities and urban environment
  • Solid Earth
  • ATMOSPHERIC COMPOSITION AND STRUCTURE
  • Pollution: urban and regional
  • Climate impacts
  • Abrupt/rapid climate change
  • COMPUTATIONAL GEOPHYSICS
  • Sea level: variations and mean
  • Sea level change
  • stadial
  • Volcano seismology
  • CRYOSPHERE
  • Pollution: urban, regional and global
  • OCEANOGRAPHY: GENERAL
  • Ocean influence of Earth rotation
  • POLICY SCIENCES
  • Earthquake ground motions and engineering seismology
  • Climate and interannual variability
  • Regional modeling

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