The radiative and geometric properties of melting first-year landfast sea ice in the Arctic

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Authors

Nathan J. M. Laxague, University of New Hampshire, DurhamFollow
Christopher J. Zappa, Columbia University
Andrew R. Mahoney, University of Alaska Fairbanks
John Goodwin, Native Village of Kotzebue
Cyrus Harris, Native Village of Kotzebue
Robert E. Schaeffer, Native Village of Kotzebue
Roswell Schaeffer, Native Village of Kotzebue, Kotzebue
Sarah Betcher, Farthest North Films
Donna D W Hauser, University of Alaska Fairbanks
Carson R. Witte, Columbia University
Jessica M. Lindsay, Columbia University
Ajit Subramaniam, Columbia University
Kate E. Turner, National Institute of Water and Atmospheric Research
Alex Whiting, Native Village of Kotzebue

Abstract

In polar regions, sea ice is a crucial mediator of the interaction between Earth's atmosphere and oceans. Its formation and breakup is intimately connected with large-scale climatic processes, local weather patterns, and the use of sea ice in coastal Arctic regions by Indigenous people. In order to investigate the physical phenomena at the heart of this process, a set of targeted, intensive observations were made over spring sea ice melt and breakup in Kotzebue Sound, Alaska. These observations were planned and executed through a collaborative effort in which an Indigenous Elder advisory council from Kotzebue and scientists participated in co-production of hypotheses and observational research, including a stronger understanding of the physical properties of sea ice during spring melt. Here we present the results of observations performed using high-endurance, fixed-wing uncrewed aerial vehicles (UAVs) containing custom-built scientific payloads. Repeated flights over the measurement period captured the early stages of the transition from a white, snow-covered state to a broken-up, bare blue-green state. We found that the reflectance of sea ice features depends strongly on their size. Snow patches get darker as they get smaller, an effect owed to the geometric relationship between the bright interior and the darker, melting feature edges. Conversely, bare patches get darker as they get larger. For the largest ice features observed, bare blue-green ice patches were found to be ≈ 20 % less reflective than average across all observational cases, while large snowy white ice patches were found to be ≈ 20 % more reflective than that same average.

Department

Mechanical Engineering

Publication Date

7-23-2024

Journal Title

The Cryosphere

Publisher

Copernicus GmbH

Digital Object Identifier (DOI)

https://dx.doi.org/10.5194/tc-18-3297-2024

Document Type

Article

Recommended Citation

Laxague, N. J. M., Zappa, C. J., Mahoney, A. R., Goodwin, J., Harris, C., Schaeffer, R. E., Schaeffer Sr., R., Betcher, S., Hauser, D. D. W., Witte, C. R., Lindsay, J. M., Subramaniam, A., Turner, K. E., and Whiting, A.: The radiative and geometric properties of melting first-year landfast sea ice in the Arctic, The Cryosphere, 18, 3297–3313, https://doi.org/10.5194/tc-18-3297-2024, 2024.

Rights

© Author(s) 2024.

Comments

This is an open access article published by Copernicus GmbH in The Cryosphere in 2024, available online: https://dx.doi.org/10.5194/tc-18-3297-2024