Saved in:
Bibliographic Details
Main Authors: Arndt, Stefanie, Meiners, Klaus M, Ricker, Robert, Krumpen, Thomas, Katlein, Christian, Nicolaus, Marcel
Format: Dataset Open Access
Language:en
Published: PANGAEA 2017
Subjects:
Online Access:https://doi.org/10.1594/PANGAEA.870706
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1867167675032010752
author Arndt, Stefanie
Meiners, Klaus M
Ricker, Robert
Krumpen, Thomas
Katlein, Christian
Nicolaus, Marcel
author_facet Arndt, Stefanie
Meiners, Klaus M
Ricker, Robert
Krumpen, Thomas
Katlein, Christian
Nicolaus, Marcel
collection Datos científicos de ciencias marinas y ambientales
contents Snow on sea ice alters the properties of the underlying ice cover as well as associated physical and biological processes at the interfaces between atmosphere, sea ice, and ocean. The Antarctic snow cover persists during most of the year and contributes significantly to the sea-ice mass due to the widespread surface flooding and related snow-ice formation. Snow also enhances the sea-ice surface reflectivity of incoming shortwave radiation and determines therefore the amount of light being reflected, absorbed, and transmitted to the upper ocean. Here, we present results of a case study of spectral solar radiation measurements under Antarctic pack ice with an instrumented Remotely Operated Vehicle in the Weddell Sea in 2013. In order to identify the key variables controlling the spatial distribution of the under-ice light regime, we exploit under-ice optical measurements in combination with simultaneous characterization of surface properties, such as sea-ice thickness and snow depth. Our results reveal that the distribution of flooded and nonflooded sea-ice areas dominates the spatial scales of under-ice light variability for areas smaller than 100 m-by-100 m. However, the heterogeneous and highly metamorphous snow on Antarctic pack ice obscures a direct correlation between the under-ice light field and snow depth. Compared to the Arctic, light levels under Antarctic pack ice are extremely low during spring (< 0. %). This is mostly a result of the distinctly different dominant sea ice and snow properties with seasonal snow cover (including strong surface melt and summer melt ponds) in the Arctic and a year-round snow cover and widespread surface flooding in the Southern Ocean.
format Dataset Open Access
id pangaea_https___doi_org_10_1594_PANGAEA_870706
institution PANGAEA
language en
publishDate 2017
publisher PANGAEA
record_format pangaea
spellingShingle Influence of snow depth and surface flooding on light transmission through Antarctic pack ice, supplementary data
Arndt, Stefanie
Meiners, Klaus M
Ricker, Robert
Krumpen, Thomas
Katlein, Christian
Nicolaus, Marcel
AWI_SeaIce; Sea Ice Physics @ AWI
Snow on sea ice alters the properties of the underlying ice cover as well as associated physical and biological processes at the interfaces between atmosphere, sea ice, and ocean. The Antarctic snow cover persists during most of the year and contributes significantly to the sea-ice mass due to the widespread surface flooding and related snow-ice formation. Snow also enhances the sea-ice surface reflectivity of incoming shortwave radiation and determines therefore the amount of light being reflected, absorbed, and transmitted to the upper ocean. Here, we present results of a case study of spectral solar radiation measurements under Antarctic pack ice with an instrumented Remotely Operated Vehicle in the Weddell Sea in 2013. In order to identify the key variables controlling the spatial distribution of the under-ice light regime, we exploit under-ice optical measurements in combination with simultaneous characterization of surface properties, such as sea-ice thickness and snow depth. Our results reveal that the distribution of flooded and nonflooded sea-ice areas dominates the spatial scales of under-ice light variability for areas smaller than 100 m-by-100 m. However, the heterogeneous and highly metamorphous snow on Antarctic pack ice obscures a direct correlation between the under-ice light field and snow depth. Compared to the Arctic, light levels under Antarctic pack ice are extremely low during spring (< 0. %). This is mostly a result of the distinctly different dominant sea ice and snow properties with seasonal snow cover (including strong surface melt and summer melt ponds) in the Arctic and a year-round snow cover and widespread surface flooding in the Southern Ocean.
title Influence of snow depth and surface flooding on light transmission through Antarctic pack ice, supplementary data
topic AWI_SeaIce; Sea Ice Physics @ AWI
url https://doi.org/10.1594/PANGAEA.870706