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Research project Feedbacks between sea ice, ocean, clouds, and aerosols in changing polar climates (ACCELERATE)

Can polar clouds dampen global warming? The current consensus states that clouds enhance surface warming in polar regions but that their impact on the net energy budget at the top of the atmosphere, and thus global climate, is either small or cooling.

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Theme

Contact person at SU

Annica Ekman

Professor of Meteorology

Department of Meteorology

08-16 23 97

annica.ekman@misu.su.se

Overview

Project period

01-01-2025 - 31-12-2029

Responsible

Department of Meteorology

Research subjects

Climate dynamics and climate change Meteorology and atmospheric science Oceanography

Status

Ongoing

Funding

Knut and Alice Wallenberg Foundation

Research groups

Circulation and connection land-sea-atmosphere

Over long timescales, the circulation systems co-evolve with ice sheets, mountain ranges, and redistributions of carbon between the atmosphere, ocean and land. The circulation and associated feedbacks influence exchanges of energy and materials between compartments of the climate system, and create teleconnections and natural climate variability.

Image: Ines Jakobsson/Stockholm University

Clouds, airborne particles and gases

A continued change in the atmospheric content of greenhouse gases and particles is estimated to result in future warming well above 1.5°C, compared with pre-industrial levels. It is uncertain how much heating is masked by the cooling effect of the particles, especially the effect of the particles on the distribution and properties of the clouds.

Clouds. Photo: Marianne Lagerklint/MISU/Stockholm University

Polar Meteorology and Oceanography

The global warming is not uniformly distributed over the Earth. The polar regions are especially sensitive for climate change and the warming in the Arctic is more than twice as fast as for the Earth on average. The effects of this warming are large, with a dramatic loss of sea ice as an example.

The icebreaker Oden on expedition in the Arctic. Photo: Michael Tjernström/MISU/Stockholm University

Figure: Schematic showing selected processes that will be studied in ACCELERATE and which interact with polar low-level clouds. Yellow arrows – solar radiation. Red arrows – infrared radiation. Green arrow – surface fluxes of aerosols and aerosol precursor gases. Brown arrow: Surface fluxes of latent and sensible heat. Blue arrow: large-scale circulation, atmospheric heat transport, and long-range transport of aerosols. Figure by Annica Ekman/MISU/Stockholm University.

This consensus is mainly based on output from global climate models, which are poor at simulating trends in polar cloud properties and radiative effects, and treat polar aerosol emissions and their influence on clouds in a rudimentary way. However, it is well-known that changes in the aerosol population can have dramatic effects on the optical properties of polar clouds.

ACCELERATE will improve our general knowledge of cloud formation and cloud feedbacks over the polar seas by developing and leveraging a novel regional-scale high-resolution model, recent and upcoming in-situ observations, and satellite data. We will conduct detailed studies of the complex interactions between sea ice, ocean, clouds, and aerosols that take place during warm-air intrusions and cold-air outbreaks in the Arctic and Antarctic.

The goal is to provide constraints on global climate models regarding polar cloud feedbacks and thereby deliver more robust future climate projections.

Project members

Project managers

Annica Ekman

Professor of Meteorology

Department of Meteorology

08-16 23 97

annica.ekman@misu.su.se

Members

Aino Kaarina Kaltiainen

PhD-student

Department of Meteorology

08-16 24 57

aino.kaltiainen@misu.su.se

Nazario Mastroianni

Scientific programmer

Department of Environmental Science

nazario.mastroianni@aces.su.se

Olivia Linke

Postdoctor

Department of Meteorology

olivia.linke@misu.su.se