The University of Southampton
×
Filter your search:
University of Southampton Institutional Repository

The potential response of the hydrate reservoir in the South Shetland Margin, Antarctic Peninsula, to ocean warming over the 21st century

The potential response of the hydrate reservoir in the South Shetland Margin, Antarctic Peninsula, to ocean warming over the 21st century
The potential response of the hydrate reservoir in the South Shetland Margin, Antarctic Peninsula, to ocean warming over the 21st century
In the South Shetland Margin (SSM), Antarctic Peninsula, a bottom-simulating reflector indicates the presence of hydrate between ca. 500 and 3000 m water depth (mwd). The cold seabed temperatures allow hydrate stability at shallower water depths. During the past five decades, the Antarctic Peninsula has been warming up faster than any other part of the Southern Hemisphere, and long-term ocean warming could affect the stability of the SSM hydrate reservoir at shallow waters. Here, we model the transient response of the SSM hydrate reservoir between 375 and 450 mwd to ocean warming for the period 1958–2100. For the period 1958–2010, seabed temperatures are given by oceanographic measurements in the area, and for 2010–2100 by two temperature scenarios represented by the observed trends for the periods 1960–2010 (0.0034°C y?1) and 1980–2010 (0.023°C y?1). Our results show no hydrate-sourced methane emissions for an ocean warming rate at the seabed of 0.0034 °C y?1. For a rate of 0.023°C y?1, emissions start in 2028 at 375 mwd and extend to 442 mwd at an average rate of about 0.91 mwd y?1, releasing ca. 1.13×103 mol y?1 of methane per metre along the margin by 2100. These emissions originate from dissociation at the top of the hydrate layer, a physical process that steady-state modelling cannot represent. Our results are speculative on account of the lack of direct evidence of a shallow water hydrate reservoir, but they illustrate that the SSM is a key area to observe the effects of ocean warming-induced hydrate dissociation in the coming decades.
Hydrate, ocean warming, methane emissions, transient modelling, South Shetland Margin, Antarctic Peninsula
0800-0395
27443
Marin-Moreno, Héctor
e466cafd-bd5c-47a1-8522-e6938e7086a4
Giustiniani, Michela
ec0161c0-0df5-4c3c-ab8b-38b7c5a3556e
Tinivella, Umberta
5e53ed76-7821-4ad9-9afb-96b4f728f787
Marin-Moreno, Héctor
e466cafd-bd5c-47a1-8522-e6938e7086a4
Giustiniani, Michela
ec0161c0-0df5-4c3c-ab8b-38b7c5a3556e
Tinivella, Umberta
5e53ed76-7821-4ad9-9afb-96b4f728f787

Marin-Moreno, Héctor, Giustiniani, Michela and Tinivella, Umberta (2015) The potential response of the hydrate reservoir in the South Shetland Margin, Antarctic Peninsula, to ocean warming over the 21st century. Polar Research, 34, 27443. (doi:10.3402/polar.v34.27443).

Record type: Article

Abstract

In the South Shetland Margin (SSM), Antarctic Peninsula, a bottom-simulating reflector indicates the presence of hydrate between ca. 500 and 3000 m water depth (mwd). The cold seabed temperatures allow hydrate stability at shallower water depths. During the past five decades, the Antarctic Peninsula has been warming up faster than any other part of the Southern Hemisphere, and long-term ocean warming could affect the stability of the SSM hydrate reservoir at shallow waters. Here, we model the transient response of the SSM hydrate reservoir between 375 and 450 mwd to ocean warming for the period 1958–2100. For the period 1958–2010, seabed temperatures are given by oceanographic measurements in the area, and for 2010–2100 by two temperature scenarios represented by the observed trends for the periods 1960–2010 (0.0034°C y?1) and 1980–2010 (0.023°C y?1). Our results show no hydrate-sourced methane emissions for an ocean warming rate at the seabed of 0.0034 °C y?1. For a rate of 0.023°C y?1, emissions start in 2028 at 375 mwd and extend to 442 mwd at an average rate of about 0.91 mwd y?1, releasing ca. 1.13×103 mol y?1 of methane per metre along the margin by 2100. These emissions originate from dissociation at the top of the hydrate layer, a physical process that steady-state modelling cannot represent. Our results are speculative on account of the lack of direct evidence of a shallow water hydrate reservoir, but they illustrate that the SSM is a key area to observe the effects of ocean warming-induced hydrate dissociation in the coming decades.

Text
27443-182828-1-PB.pdf - Version of Record
Available under License Creative Commons Attribution Non-commercial.
Download (2MB)

More information

Published date: 2015
Keywords: Hydrate, ocean warming, methane emissions, transient modelling, South Shetland Margin, Antarctic Peninsula
Organisations: Marine Geoscience
Learn more about Ocean and Earth Science research

Identifiers

Local EPrints ID: 386914
URI: http://eprints.soton.ac.uk/id/eprint/386914
DOI: doi:10.3402/polar.v34.27443
ISSN: 0800-0395
PURE UUID: f2fbcff5-c15b-40fa-af22-02d3c1e6abd1
ORCID for Héctor Marin-Moreno: ORCID iD orcid.org/0000-0002-3412-1359

Catalogue record

Date deposited: 04 Feb 2016 12:01
Last modified: 15 Mar 2024 04:14

Export record

Altmetrics

Contributors

Author: Héctor Marin-Moreno ORCID iD
Author: Michela Giustiniani
Author: Umberta Tinivella

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Library staff additional information
Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×