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Unraveling the Connection Between Canadian Wildfires and Arctic Ice Clouds

Research reveals that aerosols from Canadian wildfires of summer 2023 contributed to the formation of ice clouds over the Arctic

January 27,2025

Ice nucleating particles as a kind of aerosols have a significant impact on the Arctic climate by promoting the formation of ice clouds at a temperature above –38˚C. Wildfires in mid-latitudinal areas are a major source of these aerosols. However, a direct observation of wildfire-emitted aerosols facilitating ice cloud formation has never been documented. Now, using field and climate data, scientists from Japan have linked aerosols emitted by Canadian wildfires in 2023 to the formation of ice clouds over the Arctic Ocean.

Image title: The impact of wildfires in Canada on ice cloud formation in the Arctic.
Image Caption: Researchers from Japan suggest that organic carbon aerosols from the severe wildfires in Canada during the summer of 2023 were transported over the Arctic Ocean and contributed to the formation of ice clouds at warm temperatures.
Image Credit: Kazutoshi Sato from the National Institute of Polar Research, Japan
License Type: Original Content
Usage restrictions: Cannot be reused without permission

Clouds, composed of tiny water droplets or ice crystals, play a vital role in regulating Earth’s climate by influencing the amount of solar radiation that reaches the surface. The cloud phase significantly impacts the surface energy balance as liquid water clouds reflect more radiation than ice clouds. Ice clouds typically form at temperatures below −38°C, but recent observations indicate their formation at higher temperatures in the Arctic. This phenomenon is facilitated by ice-nucleating particles (INPs), including mineral dust, organic aerosols and bioaerosols, which promote ice cloud formation above the usual freezing point.

These INPs, primarily sourced from outsude of the Arctic refion, also include traces of organic carbon (OC) aerosols. Wildfires in Canada, Alaska, and Russia are major sources of these aerosols, contributing to higher concentrations of OC, black carbon, and other aerosols over the Arctic. However, despite extensive scientific evidence of aerosol transport from lower latitudes, a clear link between the transported aerosols and ice cloud formation in the Arctic remains unestablished.

In a recent study led by Assistant Professor Kazutoshi Sato and involving Professor Jun Inoue from the National Institute of Polar Research, Japan, scientists set out to understand how wildfire aerosols influence ice cloud formation in the Arctic. The study was made available online on December 24, 2024 and is set to be published in Volume 315 of Atmospheric Research on April 1, 2025.

The field data used in the study was gathered in September 2023 during an expedition to the Chukchi and Beaufort seas in the Arctic region aboard RV Mirai, a Japanese research vessel. The team used various instruments, including cloud particle sensor (CPS) sondes and drones, to measure particle counts and cloud properties. Additionally, atmospheric modeling tools, such as a backward trajectory model, were used to track the movement of aerosols and identify their source regions. Dr. Sato elaborates, “In the lower troposphere, our drone-based particle counter recorded particle counts two orders of magnitude higher than the voyage average. Using the CPS sonde, we detected ice clouds in the mid-troposphere under temperatures warmer than -15 °C, near a stream of warm and moist air coming from mid-latitudes. These streams are often referred to as an atmospheric river (AR). Our observations suggest that these wildfire aerosols, which have traveled via the AR, contribute to ice cloud formation under relatively warm conditions.”

Using the backward trajectory analysis, the team found that OC aerosol masses originating from wildfires in Canada traveled to the Arctic, where they contributed to ice cloud formation at temperatures warmer than usual. They traced the AR coming from the wildfire zones and found that it passed over areas with high concentrations of OC aerosols. “The AR event is a very important event for moisture transport from mid-latitudes to the polar region, and this study also shows that aerosols can be transported by this system as well,” says Prof. Inoue.

This study underscores the critical need for field-derived vertical atmospheric profiles, including the monitoring of aerosol number concentrations and their chemical composition, in developing more precise numerical modeling of the polar regions. By establishing a clear link between wildfire-emitted aerosols and ice cloud formation, this research paves the way for future endeavors that will refine how aerosol transport is represented in Arctic climate models.

Image Title: The complex interplay of factors contributing to Arctic climate system.
Image Caption: Atmospheric rivers from lower latitudes contribute to sea-ice decline, while wildfires release aerosols that may influence ice cloud formation. Ocean heat further warms the atmosphere, and volcanic eruptions release aerosols that may impact cloud formation. Together, these factors interact in a complex and dynamic manner, shaping the Arctic climate system.
Image Credit: Jun Inoue from the National Institute of Polar Research, Japan
License Type: Original Content
Usage restrictions: Cannot be reused without permission

Reference

Title of original paper: Impact of Canadian wildfires on aerosol and ice clouds in the early-autumn Arctic
Journal: Atmospheric Research
DOI: 10.1016/j.atmosres.2024.107893

About National Institute of Polar Research, Japan

Founded in 1973, the National Institute of Polar Research (NIPR) is an inter-university research institute that conducts comprehensive scientific research and observations in the polar regions. NIPR is one of the four institutes constituting the Research Organization of Information and Systems (ROIS) and engages in comprehensive research via observation stations in the Arctic and Antarctica. It strives to promote polar science by soliciting collaboration research projects publicly, as well as by providing samples, materials, and information. NIPR plays a special role as the only institute in Japan that comprehensively pursues observations and research efforts in both the Antarctic and Arctic regions.

Website: https://www.nipr.ac.jp/english/

About Assistant Professor Kazutoshi Sato from the National Institute of Polar Research, Japan

Dr. Kazutoshi Sato is an Assistant Professor at the National Institute of Polar Research. He studies climate phenomena that occur in the polar regions and explores how observational data affects numerical models. His research team mainly focuses on understanding the interaction between the atmosphere, the sea, and ice. His contributions to the field have gained recognition from Nature Communications, earning a place on the journal's Editors' Highlights page in 2021. Dr. Sato has an extensive portfolio of over 40 published papers. He is a member of the Meteorological Society of Japan, the Japan Geoscience Union, and the Oceanographic Society of Japan.

Funding information

This work was supported by Grants-in-Aid for Scientific Research (KAKENHI) and Grant-in-Aid for Transformative Research Areas of the Japan Society for the Promotion of Science (JSPS; grant numbers 24H02339, 23H00523, 22K14103) and by the Arctic Challenge for Sustainability II project, Japan (ArCS II; grant number JPMXD1420318865).

Media contact

Kazutoshi Sato
sato.kazutoshi@nipr.ac.jp

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