Evolution of the microstructure and reflectance of the surface scattering layer on melting, level Arctic sea ice

IF 4.7 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Elementa-Science of the Anthropocene Pub Date : 2023-01-01 DOI:10.1525/elementa.2022.00103

Amy R. Macfarlane, R. Dadić, M. Smith, B. Light, M. Nicolaus, Hannula Henna-Reetta, M. Webster, F. Linhardt, S. Hämmerle, M. Schneebeli

{"title":"Evolution of the microstructure and reflectance of the surface scattering layer on melting, level Arctic sea ice","authors":"Amy R. Macfarlane, R. Dadić, M. Smith, B. Light, M. Nicolaus, Hannula Henna-Reetta, M. Webster, F. Linhardt, S. Hämmerle, M. Schneebeli","doi":"10.1525/elementa.2022.00103","DOIUrl":null,"url":null,"abstract":"The microstructure of the uppermost portions of a melting Arctic sea ice cover has a disproportionately large influence on how incident sunlight is reflected and absorbed in the ice/ocean system. The surface scattering layer (SSL) effectively backscatters solar radiation and keeps the surface albedo of melting ice relatively high compared to ice with the SSL manually removed. Measurements of albedo provide information on how incoming shortwave radiation is partitioned by the SSL and have been pivotal to improving climate model parameterizations. However, the relationship between the physical and optical properties of the SSL is still poorly constrained. Until now, radiative transfer models have been the only way to infer the microstructure of the SSL. During the MOSAiC expedition of 2019–2020, we took samples and, for the first time, directly measured the microstructure of the SSL on bare sea ice using X-ray micro-computed tomography. We show that the SSL has a highly anisotropic, coarse, and porous structure, with a small optical diameter and density at the surface, increasing with depth. As the melting surface ablates, the SSL regenerates, maintaining some aspects of its microstructure throughout the melt season. We used the microstructure measurements with a radiative transfer model to improve our understanding of the relationship between physical properties and optical properties at 850 nm wavelength. When the microstructure is used as model input, we see a 10–15% overestimation of the reflectance at 850 nm. This comparison suggests that either a) spatial variability at the meter scale is important for the two in situ optical measurements and therefore a larger sample size is needed to represent the microstructure or b) future work should investigate either i) using a ray-tracing approach instead of explicitly solving the radiative transfer equation or ii) using a more appropriate radiative transfer model.","PeriodicalId":54279,"journal":{"name":"Elementa-Science of the Anthropocene","volume":"67 1","pages":""},"PeriodicalIF":4.7000,"publicationDate":"2023-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"3","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Elementa-Science of the Anthropocene","FirstCategoryId":"93","ListUrlMain":"https://doi.org/10.1525/elementa.2022.00103","RegionNum":3,"RegionCategory":"环境科学与生态学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"ENVIRONMENTAL SCIENCES","Score":null,"Total":0}

引用次数: 3

Abstract

The microstructure of the uppermost portions of a melting Arctic sea ice cover has a disproportionately large influence on how incident sunlight is reflected and absorbed in the ice/ocean system. The surface scattering layer (SSL) effectively backscatters solar radiation and keeps the surface albedo of melting ice relatively high compared to ice with the SSL manually removed. Measurements of albedo provide information on how incoming shortwave radiation is partitioned by the SSL and have been pivotal to improving climate model parameterizations. However, the relationship between the physical and optical properties of the SSL is still poorly constrained. Until now, radiative transfer models have been the only way to infer the microstructure of the SSL. During the MOSAiC expedition of 2019–2020, we took samples and, for the first time, directly measured the microstructure of the SSL on bare sea ice using X-ray micro-computed tomography. We show that the SSL has a highly anisotropic, coarse, and porous structure, with a small optical diameter and density at the surface, increasing with depth. As the melting surface ablates, the SSL regenerates, maintaining some aspects of its microstructure throughout the melt season. We used the microstructure measurements with a radiative transfer model to improve our understanding of the relationship between physical properties and optical properties at 850 nm wavelength. When the microstructure is used as model input, we see a 10–15% overestimation of the reflectance at 850 nm. This comparison suggests that either a) spatial variability at the meter scale is important for the two in situ optical measurements and therefore a larger sample size is needed to represent the microstructure or b) future work should investigate either i) using a ray-tracing approach instead of explicitly solving the radiative transfer equation or ii) using a more appropriate radiative transfer model.

查看原文本刊更多论文

融化水平北极海冰表面散射层微观结构和反射率的演变

融化的北极海冰覆盖层最上层的微观结构对入射阳光如何在冰/海洋系统中被反射和吸收具有不成比例的巨大影响。表面散射层(SSL)有效地反向散射太阳辐射，并使融化冰的表面反照率相对于人工去除SSL的冰相对较高。反照率的测量提供了入射短波辐射如何被SSL分割的信息，并且对改善气候模式参数化至关重要。然而，SSL的物理性质和光学性质之间的关系仍然很不明确。到目前为止，辐射传输模型一直是推断SSL微观结构的唯一方法。在2019-2020年的MOSAiC探险期间，我们采集了样本，并首次使用x射线显微计算机断层扫描直接测量了裸露海冰上SSL的微观结构。我们发现，SSL具有高度的各向异性，粗糙和多孔结构，具有小的光学直径和表面密度，随深度增加。随着熔化表面的消融，SSL再生，在整个熔化季节保持其微观结构的某些方面。我们利用辐射传递模型进行微观结构测量，以提高我们对850 nm波长下物理性质和光学性质之间关系的理解。当微观结构用作模型输入时，我们看到850 nm处的反射率高估了10-15%。这一比较表明，a)米尺度的空间变异性对两种原位光学测量很重要，因此需要更大的样本量来代表微观结构;b)未来的工作应该研究i)使用射线追踪方法而不是明确地求解辐射传递方程，或ii)使用更合适的辐射传递模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Elementa-Science of the Anthropocene Earth and Planetary Sciences-Atmospheric Science

CiteScore

6.90

自引率

5.10%

发文量

审稿时长

16 weeks

期刊介绍： A new open-access scientific journal, Elementa: Science of the Anthropocene publishes original research reporting on new knowledge of the Earth’s physical, chemical, and biological systems; interactions between human and natural systems; and steps that can be taken to mitigate and adapt to global change. Elementa reports on fundamental advancements in research organized initially into six knowledge domains, embracing the concept that basic knowledge can foster sustainable solutions for society. Elementa is published on an open-access, public-good basis—available freely and immediately to the world.