Drivers of late Holocene ice core chemistry in Dronning Maud Land: the context for the ISOL-ICE project

IF 3.8 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Climate of The Past Pub Date : 2024-05-28 DOI:10.5194/cp-20-1213-2024
V. Holly L. Winton, Robert Mulvaney, Joel Savarino, Kyle R. Clem, Markus M. Frey
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Abstract

Abstract. Within the framework of the Isotopic Constraints on Past Ozone Layer in Polar Ice (ISOL-ICE) project, we present initial ice core results from the new ISOL-ICE ice core covering the last millennium from high-elevation Dronning Maud Land (DML) and discuss the implications for interpreting the stable isotopic composition of nitrogen in ice core nitrate (δ15N(NO3-)) as a surface ultra-violet radiation (UV) and total column ozone (TCO) proxy. In the quest to derive TCO using δ15N(NO3-), an understanding of past snow accumulation changes, as well as aerosol source regions and present-day drivers of their variability, is required. We therefore report here the ice core age–depth model, the snow accumulation and ice chemistry records, and correlation analysis of these records with climate variables over the observational era (1979–2016). The ISOL-ICE ice core covers the last 1349 years from 668 to 2017 CE ± 3 years, extending previous ice core records from the region by 2 decades towards the present and shows excellent reproducibility with those records. The extended ISOL-ICE record of last 2 decades showed a continuation of the methane sulfonate (MSA−) increase from ∼ 1800 to present while there were less frequent large deposition events of sea salts relative to the last millennium. While our chemical data do not allow us to distinguish the ultimate (sea ice or the open ocean) source of sea salt aerosols in DML winter aerosol, our correlation analysis clearly suggests that it is mainly the variability in atmospheric transport and not the sea ice extent that explains the interannual variability in sea salt concentrations in DML. Correlation of the snow accumulation record with climate variables over the observational era showed that precipitation at ISOL-ICE is predominately derived from the South Atlantic with onshore winds delivering marine air masses to the site. The snow accumulation rate was stable over the last millennium with no notable trends over the last 2 decades relative to the last millennium. Interannual variability in the accumulation record, ranging between 2 and 20 cm a−1 (w.e.), would influence the ice core δ15N(NO3-) record. The mean snow accumulation rate of 6.5±2.4 cm a−1 (w.e.) falls within the range suitable for reconstructing surface mass balance from ice core δ15N(NO3-), highlighting that the ISOL-ICE ice core δ15N(NO3-) can be used to reconstruct either the surface mass balance or surface UV if the ice core δ15N(NO3-) is corrected for the snow accumulation influence, thereby leaving the UV imprint in the δ15N(NO3-) ice core record to quantify natural ozone variability.
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德龙宁毛德地全新世晚期冰芯化学的驱动因素:ISOL-ICE 项目的背景
摘要在极地冰层过去臭氧层同位素约束(ISOL-ICE)项目框架内,我们介绍了来自高海拔德龙宁毛德地(Dronning Maud Land,DML)、涵盖过去千年的新 ISOL-ICE 冰芯的初步冰芯结果,并讨论了将冰芯硝酸盐(δ15N(NO3-))中氮的稳定同位素组成解释为地表紫外线辐射(UV)和总臭氧柱(TCO)替代物的影响。在利用δ15N(NO3-)推导总臭氧消耗量的过程中,需要了解过去积雪的变化、气溶胶来源区域及其变化的现今驱动因素。因此,我们在此报告冰芯年龄深度模型、积雪和冰化学记录,以及这些记录与观测时代(1979-2016 年)气候变量的相关性分析。ISOL-ICE冰芯覆盖了从公元668年到2017年(±3年)的过去1349年,将该地区以前的冰芯记录向现在延伸了20年,并显示出与这些记录极佳的重现性。过去 20 年的 ISOL-ICE 扩展记录显示,从 1800 年至今,甲烷磺酸盐(MSA-)继续增加,而相对于上一个千年,海盐的大规模沉积事件则较少。虽然我们的化学数据无法让我们区分 DML 冬季气溶胶中海盐气溶胶的最终来源(海冰或公海),但我们的相关性分析清楚地表明,主要是大气传输的变化而不是海冰范围解释了 DML 中海盐浓度的年际变化。积雪记录与观测期间气候变量的相关性表明,ISOL-ICE 的降水主要来自南大西洋,陆风将海洋气团输送到该地。积雪率在上一个千年中保持稳定,与上一个千年相比,过去 20 年没有明显的趋势。积雪记录的年际变化范围在 2 到 20 cm a-1(湿重)之间,这将影响冰芯 δ15N(NO3-)记录。6.5±2.4 cm a-1 (w.e.) 的平均积雪率在适合重建冰芯δ15N(NO3-)记录的范围内。如果对冰芯 δ15N(NO3-)进行积雪影响校正,则 ISOL-ICE 冰芯 δ15N(NO3-)可用于重建地表质量平衡或地表紫外线,从而在 δ15N(NO3-)冰芯记录中留下紫外线印记,以量化臭氧的自然变化。
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来源期刊
Climate of The Past
Climate of The Past 地学-气象与大气科学
CiteScore
7.40
自引率
14.00%
发文量
120
审稿时长
4-8 weeks
期刊介绍: Climate of the Past (CP) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on the climate history of the Earth. CP covers all temporal scales of climate change and variability, from geological time through to multidecadal studies of the last century. Studies focusing mainly on present and future climate are not within scope. The main subject areas are the following: reconstructions of past climate based on instrumental and historical data as well as proxy data from marine and terrestrial (including ice) archives; development and validation of new proxies, improvements of the precision and accuracy of proxy data; theoretical and empirical studies of processes in and feedback mechanisms between all climate system components in relation to past climate change on all space scales and timescales; simulation of past climate and model-based interpretation of palaeoclimate data for a better understanding of present and future climate variability and climate change.
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