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Covariation of Sea ice and methanesulphonic acid in Wilhelm II Land, East Antarctica

Published online by Cambridge University Press:  14 September 2017

Annette F.M. Foster ,
Mark A.J. Curran ,
Barbara T. Smith ,
Tas D. Van Ommen  and
Vin I. Morgan
Annette F.M. Foster
Affiliation:
Institute of Antarctic and Southern Ocean Studies, University of Tasmania, Private Bag 77, Hobart, Tasmania 7001, Australia
Mark A.J. Curran
Affiliation:
Australian Government Antarctic Division and Antarctic and Climate Ecosystems CRC, Private Bag 80, Hobart, Tasmania 7001, Australia, E-mail: mark.curran@utas.edu.au
Barbara T. Smith
Affiliation:
Australian Government Antarctic Division and Antarctic and Climate Ecosystems CRC, Private Bag 80, Hobart, Tasmania 7001, Australia, E-mail: mark.curran@utas.edu.au
Tas D. Van Ommen
Affiliation:
Australian Government Antarctic Division and Antarctic and Climate Ecosystems CRC, Private Bag 80, Hobart, Tasmania 7001, Australia, E-mail: mark.curran@utas.edu.au
Vin I. Morgan
Affiliation:
Australian Government Antarctic Division and Antarctic and Climate Ecosystems CRC, Private Bag 80, Hobart, Tasmania 7001, Australia, E-mail: mark.curran@utas.edu.au
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Abstract

Sea ice plays an important role in ocean–atmosphere heat exchange, global albedo and the marine ecosystem. Knowledge of variation in Sea-ice extent is essential in order to understand past climates, and to model possible future climate Scenarios. This paper presents results from a Short firn core Spanning 15 years collected from near Mount Brown, Wilhelm II Land, East Antarctica. Variations of methanesulphonic acid (MSA) at Mount Brown were positively correlated with Sea-ice extent from the coastal region Surrounding Mount Brown (60–120˚ E) and from around the entire Antarctic coast (0–360˚ E). Previous results from Law Dome identified this MSA–sea-ice relationship and proposed it as an Antarctic Sea-ice proxy (Curran and others, 2003), with the Strongest results found for the local Law Dome region. Our data provide Supporting evidence for the Law Dome proxy (at another Site in East Antarctica), but a deeper Mount Brown ice core is required to confirm the Sea-ice decline Suggested by Curran and others (2003). Results also indicate that this deeper record may also provide a more circum-Antarctic Sea-ice proxy.

Type
Research Article
Information
Annals of Glaciology , Volume 44 , 2006 , pp. 429 - 432
Copyright
Copyright © The Author(s) [year] 2006 

Introduction

Research utilizing antarctic ice cores aims to investigate climate connections between the Southern ocean and the atmosphere. antarctic Sea ice plays an essential role in regulation of the global climate, ocean circulation and biological productivity. in order to understand the link between Sea ice and climate, an understanding of the variations in Sea-ice extent is required (nicol and allison, 1997; Reference Wolff, Rankin and RöthlisbergerWu and others, 1999). antarctic Sea-ice extent has been found to respond to interannual climate variability arising from the el niño–southern oscillation (ENSO) phenomenon (Reference Meyerson, Mayewski, Kreutz, Meeker, Whitlow and TwicklerMeyerson and others, 2002), and Sea ice is expected to be a Sensitive indicator of climate change, declining in extent in response to higher atmospheric and oceanic temperatures (Reference Jacka and BuddJacka and budd, 1998; Reference WilsonWolff and others, 2003). however, Some models Suggest that, with global warming, Sea-ice extent is increasing due to the Stabilizing effects of increased Snowfall on the Southern ocean (Reference Wu, Budd and JackaZwally and others, 2002; Reference Nicol and AllisonWolffParkinson, 2004). longer records are needed to fully understand the driving mechanisms behind Sea-ice extent variability.

Satellite records of Sea-ice extent Span only the past few decades, So detecting a long-term trend from within the interannual variability of the Sea-ice record is problematic. identification of a proxy record of Sea-ice extent would allow investigation of variability prior to Satellite observation, thereby offering insights into long-term trends in Sea-ice extent in east antarctica. evidence from ice-core chemistry records Suggests that there is a link between methanesulphonic acid (MSA) production rates and Sea-ice extent (Reference Smith, van and MorganWelch and others, 1993; Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003). MSA forms from oxidation of dimethylsulphide (DMS) produced by phytoplankton in the Surface ocean water, with productivity directly influenced by Sea ice and climatic factors Such as ENSO (Reference Curran, Jones and BurtonCurran and others, 1998b; Reference Meyerson, Mayewski, Kreutz, Meeker, Whitlow and TwicklerMeyerson and others, 2002). analysis of the MSA from a law dome ice core identified a Significant correlation between the concentration of MSA and the extent of Sea ice around the entire continent, with a Stronger correlation for the local region of 80–140˚ e (Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003). this Suggests that the law dome MSA record can be used as a Sea-ice proxy for this region (Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003). the law dome MSA–sea-ice proxy indicates that there has been a decline in regional Sea-ice extent Since the 1950s (Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003),which is in agreement with other climate proxy Studies that have also reported a decline in antarctic Sea ice (Reference De la MareDe la mare, 1997; Reference Wolff, Rankin and RöthlisbergerWu and others, 1999; Reference Barbraud and WeimerskirchBarbraud andweimerskirch, 2001; Reference Whitlow, Mayewski and DibbWilson and others, 2001). the MSA–sea-ice proxy identified by Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others (2003) was derived from a Single ice-core record. data from other ice-core Sites throughout antarctica are required to confirm the validity of the MSA–sea-ice proxy and allow further investigation of Sea-ice variability around antarctica, and the longer-term trends in Sea-ice extent.

Satellite records of Sea-ice extent Span only the past few decades, So detecting a long-term trend from within the interannual variability of the Sea-ice record is problematic. identification of a proxy record of Sea-ice extent would allow investigation of variability prior to Satellite observation, thereby offering insights into long-term trends in Sea-ice extent in east antarctica. evidence from ice-core chemistry records Suggests that there is a link between methanesulphonic acid (MSA) production rates and Sea-ice extent (Reference Smith, van and MorganWelch and others, 1993; Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003). MSA forms from oxidation of dimethylsulphide (DMS) produced by phytoplankton in the Surface ocean water, with productivity directly influenced by Sea ice and climatic factors Such as ENSO (Reference CurranCurran and others, 1998b; Reference Meyerson, Mayewski, Kreutz, Meeker, Whitlow and TwicklerMeyerson and others, 2002). analysis of the MSA from a law dome ice core identified a Significant correlation between the concentration of MSA and the extent of Sea ice around the entire continent, with a Stronger correlation for the local region of 80–140˚ e (Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003). this Suggests that the law dome MSA record can be used as a Sea-ice proxy for this region (Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003). the law dome MSA–sea-ice proxy indicates that there has been a decline in regional Sea-ice extent Since the 1950s (Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003),which is in agreement with other climate proxy Studies that have also reported a decline in antarctic Sea ice (Reference De la MareDe la mare, 1997; Reference Wolff, Rankin and RöthlisbergerWu and others, 1999; Reference Barbraud and WeimerskirchBarbraud andweimerskirch, 2001; Reference Whitlow, Mayewski and DibbWilson and others, 2001). the MSA–sea-ice proxy identified by Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others (2003) was derived from a Single ice-core record. data from other ice-core Sites throughout antarctica are required to confirm the validity of the MSA–sea-ice proxy and allow further investigation of Sea-ice variability around antarctica, and the longer-term trends in Sea-ice extent.

This paper focuses on the record of MSA extracted from a Short firn core collected from wilhelm ii land, east antarctica, and explores links between local Sea-ice extent and MSA concentration, with comparison to the law dome MSA–sea-ice proxy proposed by Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others (2003).

Sampling and Analysis

A 10 m firn core was drilled using a hand auger near mount brown (69.131˚ S, 85.997˚ e; 2078ma.s.l.) as part of a larger Survey in wilhelm ii land (fig. 1) (Reference Pasteur and MulvaneySmith and ruddell, 2001; Reference Smith and RuddellSmith and others, 2002). wilhelm ii land is located inland of the west ice Shelf, on the main east antarctic ice Sheet Sloping towards the northwest/north-northwest, and is dominated by winds which Sweep from the Southeast across this Sector of east antarctica, as well as locally generated katabatic winds (Reference King and TurnerKing and turner, 1997).

Fig. 1. Location of the Mount Brown firn core (MBS) in Wilhelm II Land (after Reference Pasteur and MulvaneySmith and Ruddell, 2001).

After collection, the mount brown firn core was Sectioned into approximately 1 m lengths and Sealed in plastic (Reference Pasteur and MulvaneySmith and ruddell, 2001). all cores were then Stored in plastic core trays within insulated pvc bags and Stored at –18˚c in a blast freezer aboard the R/v Aurora Australis (Reference Pasteur and MulvaneySmith and ruddell, 2001) until return to australian government antarctic division laboratories in hobart.

The mount brown firn core was initially measured for a range of parameters including electrical conductivity, hydrogen peroxide (H2o2) and oxygen isotope ratio (δ18o) relative to vienna Standard mean ocean water (VSMOW) (Reference Smith and RuddellSmith and others, 2002). the core was then further Sampled for a Suite of trace ions (including msa) in 2003 using the established Sampling techniques and Suppressed ion chromatography methods of Reference Curran and PalmerCurran and palmer (2001). typical precision on the msa measurements is 4%.

Mount brown is located Sufficiently close to the coast to receive adequate accumulation to record Seasonal variations in trace chemistry. a detailed Stratigraphy of the firn core was undertaken prior to Sampling, with no visible Signs of melt present (Reference Pasteur and MulvaneySmith and ruddell, 2001).

Dating the Firn Core

The mount brown chemical record contained Seasonal cycles, which were used to date the firn core. Seasonal cycles in trace chemicals have been Successfully used to date ice cores elsewhere in antarctica (e.g. Reference Legrand and DelmasLegrand and delmas, 1985; Reference Welch, Mayewski and WhitlowWhitlow and others, 1992; Reference Mosley-Thompson, Thompson, Dai, Davis and LinMosley-thompson and others, 1993; Reference Minikin, Wagenbach, Graf and KipfstuhlMinikin and others, 1994; Reference Curran, van Ommen and MorganCurran and others, 1998a). a multi-species approach using the H2o2 record as the primary marker was undertaken (see Reference Morgan and van OmmenMorgan and van ommen, 1997), with year beginnings defined to coincide with the Summer maxima in the H2o2 record (assumed to be at the Summer Solstice) (fig. 2). Reference Pasteur and MulvaneySmith and ruddell (2001) used the δ18o, H2o2 and electrical conductivity records to date the mount brown core. the addition of trace chemical records in 2003 revised the initial dating Scheme and determined that the mount brown core Spanned 15 years, from 1984 to 1999. the trace chemical record was particularly useful in resolving Sections of the firn core where the Summer marker (H2o2) became unclear. for example, msa was also used as a Summer marker (fig. 2). Support for this new dating Scheme was provided by an increase in the Sulphate Signal during 1992–94 from the volcanic eruption of pinatubo, philippines, (in 1991) and cross-matching of chemical Signals (including the pinatubo eruption) in a nearby core that Spanned 7 years (1992–98). while there may be Some uncertainty with the dating process below the pinatubo eruption, it is unlikely to be more than ±1 year, and does not affect the findings presented in this paper.

Fig. 2. Mount Brown MSA and H2O2 records, with year markers indicated by grey triangles.

Comparison With Sea-Ice Records

It is well documented for antarctica that with increasing distance inland and elevation, there is a decreased dominance of marine air masses and an increase in Stratospheric Source Strength, which is reflected in the trace chemical record preserved in the ice (e.g. Reference BromwichBromwich, 1988; Reference Mulvaney and WolffMulvaney and wolff, 1994; Reference Legrand and MayewskiLegrand and mayewski, 1997; Reference Kreutz and MayewskiKreutz and mayewski, 1999). this is also known to have a direct effect on the local accumulation rate (Reference BromwichBromwich, 1988). the mount brown firn core Site (MBS) is located at 2078 ma.s.l. (fig. 1) and approximately 200 km inland of the west ice Shelf (Reference Pasteur and MulvaneySmith and ruddell, 2001) and is estimated here to receive 297 kgm–2 a–1. in contrast, law dome projects out from the coast of east antarctica, with the Summit of the dome at 1370ma.s.l., and receives approximately 640 kgm–2 a–1 (Reference Morgan, Wookey, Li, van Ommen, Skinner and FitzpatrickMorgan and others, 1997; Reference Curran, van Ommen and MorganCurran and others, 1998a). accumulation rates of >200 kgm–2 a–1 are considered to be Sufficient to preserve Seasonal cycles in trace chemicals (Reference Legrand and MayewskiLegrand and mayewski, 1997).

Msa is reported to exhibit post-depositional movement, which may involve chemical reactions within the Snowpack or a loss of msa from the Snowpack (Reference ParkinsonPasteur and mulvaney, 2000; Reference CurranCurran and others, 2002; Reference Delmas, Wagnon, K., Kamiyama and WatanabeDelmas and others, 2003). the movement of msa is believed to be related to the accumulation rate and the concentration of other trace chemicals within the Snowpack (Reference ParkinsonPasteur and mulvaney, 2000). this is most common in ice cores collected from regions with low accumulation rates. on examination of the Seasonal record of msa, there was no evidence of post-depositional movement of msa in the mount brown record.

The Seasonal record of msa from mount brown was compared to Sea-ice extent records using the Same method as Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others (2003). austral Summer-centred mean annual msa concentrations were calculated for the 15 year ice-core record from mount brown (1984–98). the 15 year Sea-ice extent record was obtained from mean monthly passive microwave data compiled by T.h. jacka (data available on the antarctic climate and ecosystems cooperative research centre climate datasets website, http://staff.acecrc.org.au/∽jacka/climate). using the Same method as detailed in Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others (2003), the Sea-ice extent for each year was calculated from the mean ice-edge latitude (15% ice concentration) of august, September and october for each year. the msa record from mount brown was compared with the Sea-ice extent averaged from around the entire continent and then with each 10˚ Sector of longitude (fig. 3). we acknowledge that this comparison is limited due to the Short ice-core record from mount brown, but we find Significant results with this comparison. while Sea ice in the Sector (80˚ e) containing mount brown is not correlated with msa, the wider 60–120˚ e Surrounding Sector is Significantly correlated (r = 0.51, p < 0.05, n = 15; fig. 4a). this Suggests that the msa Signal is affected by atmospheric transport and mixing processes across a wider Source region (60–120˚ e) before reaching mount brown. however, due to the Short length of this record (15 years), we are unable to identify Specific msa Source regions to mount brown. in addition, the Strongest correlation was found between mount brown and mean annual maximum Sea-ice extent around the whole continent (r = 0.70, p < 0.005, n = 15; fig. 4b). this is not Significantly Stronger than the 60–120˚ e Sector (r = 0.51), mainly due to the Small number of years (n = 15), but Suggests that a longer core from mount brown may provide a Sea-ice proxy that better represents the circum-antarctic Sea-ice Signal.

Fig. 3. Correlation coefficient between MSA at Mount Brown and Law Dome vs Sea-ice extent at each longitude around Antarctica, between 1998 and 1994, where the vertical dotted line indicates the longitude of Mount Brown, and the Shaded rectangle the local region (60–120˚ E).

Fig. 4. Correlation between austral Summer-centred mean annual MSA concentrations from Mount Brown (1984–98) and the local region (60–120˚ E; 1985–97) (a) and Sea-ice extent from around the whole continent (0–360˚ E; 1985–97) (b).

The Sector 200–220˚ e, which occurs in the ross Sea, is also found to be Significantly correlated with msa concentrations at mount brown (r = 0.53, p < 0.05, n = 15; fig. 3). the law dome msa record was also correlated with Sea-ice variations in the ross Sea region (Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003), and was most likely due to autocorrelations within the Sea-ice distribution, rather than transport of msa from the ross Sea region to law dome.

The law dome msa record has been proposed as a Sea-ice extent proxy, with the msa record Suggesting a decline in antarctic Sea-ice extent Since the 1950s (Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others, 2003). comparisons between the preserved msa record from law dome and mount brown Suggest that a longer record taken from mount brown could help to confirm the trends Seen in the law dome msa record (fig. 5). this could help to confirm the law dome msa record as a proxy for Sea-ice extent over time-spans not covered by instrumental data.

Fig. 5. Comparison of the Law Dome MSA record (1960–95; 3 year running mean) and the Mount Brown MSA record (1984–98; 3 year running mean). Note that the curves are offset due to differences in mean MSA concentration, which are due to differences in the Source and transport of MSA.

Conclusions

Research on the preserved trace chemical record of msa from law dome by Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others (2003) has identified a relationship between the concentration of msa and Sea-ice extent. however, this proxy is currently only applicable to msa records from law dome. we have identified another Site, near mount brown, located in wilhelm ii land on the main east antarctic ice Sheet, where the MSA–sea-ice proxy also appears to be valid, thus Supporting the law dome MSA–sea-ice proxy. further research using a longer core from this Site or nearby in wilhelm ii land would improve the validation of the law dome MSA–sea-ice proxy, and further assess the decline in Sea-ice extent reported by Reference Curran, van Ommen, Morgan, Phillips and PalmerCurran and others (2003). investigations of msa proxies from more Sites around antarctica are required before large-scale generalizations about variations in Sea-ice extent around antarctica may be Stated. the use of an MSA–sea-ice proxy, at least in Some coastal areas, may assist in understanding the link between marine biological activity, Sea-ice extent and past climate change events, and therefore assist in modelling of future climate conditions.

Acknowledgement

This work was Supported by the australian government’s cooperative research centres programme through the antarctic climate and ecosystems cooperative research centre (ace crc).

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Figure 0

Fig. 1. Location of the Mount Brown firn core (MBS) in Wilhelm II Land (after Smith and Ruddell, 2001).

Figure 1

Fig. 2. Mount Brown MSA and H2O2 records, with year markers indicated by grey triangles.

Figure 2

Fig. 3. Correlation coefficient between MSA at Mount Brown and Law Dome vs Sea-ice extent at each longitude around Antarctica, between 1998 and 1994, where the vertical dotted line indicates the longitude of Mount Brown, and the Shaded rectangle the local region (60–120˚ E).

Figure 3

Fig. 4. Correlation between austral Summer-centred mean annual MSA concentrations from Mount Brown (1984–98) and the local region (60–120˚ E; 1985–97) (a) and Sea-ice extent from around the whole continent (0–360˚ E; 1985–97) (b).

Figure 4

Fig. 5. Comparison of the Law Dome MSA record (1960–95; 3 year running mean) and the Mount Brown MSA record (1984–98; 3 year running mean). Note that the curves are offset due to differences in mean MSA concentration, which are due to differences in the Source and transport of MSA.