Year-long ground-based observations of bromine oxide over Bharati Station, Antarctica

IF 1.5 4区地球科学 Q3 ECOLOGY

Polar Science Pub Date : 2023-12-01 DOI:10.1016/j.polar.2023.100977

Shrutika P. Wagh , Sankirna D. Joge , Surendra Singh , Prithviraj Mali , Steffen Beirle , Thomas Wagner , Silvia Bucci , Alfonso Saiz-Lopez , Rohini Bhawar , Anoop S. Mahajan

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引用次数: 0

Abstract

Bromine chemistry plays an important role in tropospheric ozone depletion events in polar regions. Autocatalytic reactions lead to bromine explosion events, causing ozone depletion to near-zero levels in the polar troposphere. Bromine chemistry over Antarctica is not fully understood, and ground-based observations are scarce. This work presents year-long observations of bromine oxide (BrO) over the Bharati station (69.41°S, 76.19°E) using Multi-axis Differential Optical Absorption Spectroscopy (MAX-DOAS) from December 2018 to February 2020. The results show that elevated BrO mixing ratios were found during spring (September), with a maximum value of 10.21 ± 4.38 pptv for clear sky conditions and 33.15 ± 2.23 pptv for cloudy conditions. BrO was not observed above the detection limit (∼3 × 10¹³ molecule cm⁻²) outside spring on clear days. In general, lower mixing ratios were observed on clear days over Bharati compared to stations in West Antarctica. This indicates a different source strength over East Antarctica compared to West Antarctica. BrO vertical column densities were high during spring, with a maximum value of 1.34 ± 0.35 × 10¹⁴ molecule cm⁻². The vertical profiles of the BrO mixing ratios show a peak at the surface during spring (average of 6.5 ± 1.91 pptv), decreasing sharply with altitude. Back trajectories show that air masses passing over the first year ice showed higher BrO, although factors such as meteorology play an important role in determining the absolute levels. Using a box model, we show that bromine chemistry can deplete as much as 2.15 ppb of ozone in a day at the Bharati Station on clear days, which shows that it does not lead to complete ozone depletion events over Bharati.

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南极巴拉蒂站上空溴氧化物的一年地面观测

溴化学在极地对流层臭氧消耗事件中发挥着重要作用。自催化反应导致溴爆炸事件，使极地对流层的臭氧消耗接近零水平。人们对南极上空的溴化学还不完全了解，地面观测也很少。这项工作介绍了 2018 年 12 月至 2020 年 2 月期间利用多轴差分光学吸收光谱（MAX-DOAS）对巴拉蒂站（南纬 69.41 度，东经 76.19 度）上空的溴氧化物（BrO）进行的长达一年的观测。结果显示，春季（9 月）发现 BrO 混合比升高，晴天条件下最大值为 10.21 ± 4.38 pptv，阴天条件下最大值为 33.15 ± 2.23 pptv。在春季以外的晴天，没有观测到溴氧化物超过检测限（∼3 × 1013 摩尔 cm-2）。总体而言，与南极洲西部的观测站相比，巴拉蒂晴天观测到的混合比更低。这表明南极洲东部与南极洲西部的源强度不同。春季的 BrO 垂直柱密度较高，最大值为 1.34 ± 0.35 × 1014 摩尔 cm-2。溴氧化物混合比的垂直剖面图显示，春季地表出现一个峰值（平均值为 6.5 ± 1.91 pptv），随着高度的升高而急剧下降。返回轨迹显示，经过第一年冰层上空的气团显示出更高的氧化溴，尽管气象等因素在决定绝对水平方面起着重要作用。通过箱式模型，我们发现在晴朗的日子里，溴的化学作用可以在一天之内消耗巴拉蒂站多达 2.15 ppb 的臭氧，这表明溴并不会导致巴拉蒂上空臭氧的完全消耗。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Polar Science ECOLOGY-GEOSCIENCES, MULTIDISCIPLINARY

CiteScore

3.90

自引率

5.60%

发文量

期刊介绍： Polar Science is an international, peer-reviewed quarterly journal. It is dedicated to publishing original research articles for sciences relating to the polar regions of the Earth and other planets. Polar Science aims to cover 15 disciplines which are listed below; they cover most aspects of physical sciences, geosciences and life sciences, together with engineering and social sciences. Articles should attract the interest of broad polar science communities, and not be limited to the interests of those who work under specific research subjects. Polar Science also has an Open Archive whereby published articles are made freely available from ScienceDirect after an embargo period of 24 months from the date of publication. - Space and upper atmosphere physics - Atmospheric science/climatology - Glaciology - Oceanography/sea ice studies - Geology/petrology - Solid earth geophysics/seismology - Marine Earth science - Geomorphology/Cenozoic-Quaternary geology - Meteoritics - Terrestrial biology - Marine biology - Animal ecology - Environment - Polar Engineering - Humanities and social sciences.