Replication Data for: High-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an Arctic seepage site

Abstract: Methane (CH4) in marine sediments has the potential to contribute to changes in the ocean- and climate system. Physical and biochemical processes that are difficult to quantify with current standard methods such as acoustic surveys and discrete sampling govern the distribution of dissolved...

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Main Authors:	Jansson, Pär, Triest, Jack, Grilli, Roberto, Ferré, Benedicte, Silyakova, Anna, Mienert, Jürgen, Chappellaz, Jérôme
Format:	Other/Unknown Material
Language:	unknown
Published:	DataverseNO 2015
Subjects:	Earth and Environmental Sciences Methane Sensing Arctic Ocean acidification Svalbard
Online Access:	https://doi.org/10.18710/UWP6LL

id	ftdataverseno:doi:10.18710/UWP6LL
record_format	openpolar
spelling	ftdataverseno:doi:10.18710/UWP6LL 2023-10-29T02:34:15+01:00 Replication Data for: High-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an Arctic seepage site Jansson, Pär Triest, Jack Grilli, Roberto Ferré, Benedicte Silyakova, Anna Mienert, Jürgen Chappellaz, Jérôme Jansson, Pär 2015-10-23 https://doi.org/10.18710/UWP6LL unknown DataverseNO https://doi.org/10.18710/UWP6LL Earth and Environmental Sciences Methane Sensing Under-water sensor data and hydroacoustic data 2015 ftdataverseno https://doi.org/10.18710/UWP6LL 2023-10-04T22:56:36Z Abstract: Methane (CH4) in marine sediments has the potential to contribute to changes in the ocean- and climate system. Physical and biochemical processes that are difficult to quantify with current standard methods such as acoustic surveys and discrete sampling govern the distribution of dissolved CH4 in oceans and lakes. Detailed observations of aquatic CH4 concentrations are required for a better understanding of CH4 dynamics in the water column, how it can affect lake- and ocean acidification, the chemosynthetic ecosystem, and mixing ratios of atmospheric climate gases. Here we present pioneering high-resolution in-situ measurements of dissolved CH4 throughout the water column over a 400 m deep CH4 seepage area at the continental slope west of Svalbard. A new fast-response under-water membrane-inlet laser spectrometer sensor demonstrates technological advances and breakthroughs for ocean measurements. We reveal decametre-scale variations of dissolved CH4 concentrations over the CH4 seepage zone. Previous studies could not resolve such heterogeneity in the area, assumed smoother distribution and therefore lacked both details and insights to ongoing processes. We show good repeatability of the instrument measurements, which are also in agreement with discrete sampling. New numerical models, based on acoustically evidenced free gas emissions from the seafloor, support the observed heterogeneity and CH4 inventory. We identified sources of CH4, undetectable with echosounder, and rapid diffusion of dissolved CH4 away from the sources. Results from the continuous ocean laser-spectrometer measurements, supported by modelling, improve our understanding of CH4 fluxes and related physical processes over Arctic CH4 degassing regions. Other/Unknown Material Arctic Ocean acidification Svalbard DataverseNO
institution	Open Polar
collection	DataverseNO
op_collection_id	ftdataverseno
language	unknown
topic	Earth and Environmental Sciences Methane Sensing
spellingShingle	Earth and Environmental Sciences Methane Sensing Jansson, Pär Triest, Jack Grilli, Roberto Ferré, Benedicte Silyakova, Anna Mienert, Jürgen Chappellaz, Jérôme Replication Data for: High-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an Arctic seepage site
topic_facet	Earth and Environmental Sciences Methane Sensing
description	Abstract: Methane (CH4) in marine sediments has the potential to contribute to changes in the ocean- and climate system. Physical and biochemical processes that are difficult to quantify with current standard methods such as acoustic surveys and discrete sampling govern the distribution of dissolved CH4 in oceans and lakes. Detailed observations of aquatic CH4 concentrations are required for a better understanding of CH4 dynamics in the water column, how it can affect lake- and ocean acidification, the chemosynthetic ecosystem, and mixing ratios of atmospheric climate gases. Here we present pioneering high-resolution in-situ measurements of dissolved CH4 throughout the water column over a 400 m deep CH4 seepage area at the continental slope west of Svalbard. A new fast-response under-water membrane-inlet laser spectrometer sensor demonstrates technological advances and breakthroughs for ocean measurements. We reveal decametre-scale variations of dissolved CH4 concentrations over the CH4 seepage zone. Previous studies could not resolve such heterogeneity in the area, assumed smoother distribution and therefore lacked both details and insights to ongoing processes. We show good repeatability of the instrument measurements, which are also in agreement with discrete sampling. New numerical models, based on acoustically evidenced free gas emissions from the seafloor, support the observed heterogeneity and CH4 inventory. We identified sources of CH4, undetectable with echosounder, and rapid diffusion of dissolved CH4 away from the sources. Results from the continuous ocean laser-spectrometer measurements, supported by modelling, improve our understanding of CH4 fluxes and related physical processes over Arctic CH4 degassing regions.
author2	Jansson, Pär
format	Other/Unknown Material
author	Jansson, Pär Triest, Jack Grilli, Roberto Ferré, Benedicte Silyakova, Anna Mienert, Jürgen Chappellaz, Jérôme
author_facet	Jansson, Pär Triest, Jack Grilli, Roberto Ferré, Benedicte Silyakova, Anna Mienert, Jürgen Chappellaz, Jérôme
author_sort	Jansson, Pär
title	Replication Data for: High-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an Arctic seepage site
title_short	Replication Data for: High-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an Arctic seepage site
title_full	Replication Data for: High-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an Arctic seepage site
title_fullStr	Replication Data for: High-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an Arctic seepage site
title_full_unstemmed	Replication Data for: High-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an Arctic seepage site
title_sort	replication data for: high-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an arctic seepage site
publisher	DataverseNO
publishDate	2015
url	https://doi.org/10.18710/UWP6LL
genre	Arctic Ocean acidification Svalbard
genre_facet	Arctic Ocean acidification Svalbard
op_relation	https://doi.org/10.18710/UWP6LL
op_doi	https://doi.org/10.18710/UWP6LL
_version_	1781056737865891840

Replication Data for: High-resolution underwater laser spectrometer sensing provides new insights into methane distribution at an Arctic seepage site

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