Depth-resolved photochemical production of hydrogen peroxide in the global ocean using remotely sensed ocean color

Yuting Zhu, L. Powers, D. Kieber, W. Miller
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引用次数: 2

Abstract

Hydrogen peroxide (H2O2) is an important reactive oxygen species (ROS) in natural waters, affecting water quality via participation in metal redox reactions and causing oxidative stress for marine ecosystems. While attempts have been made to better understand H2O2 dynamics in the global ocean, the relative importance of various H2O2 sources and losses remains uncertain. Our model improves previous estimates of photochemical H2O2 production rates by using remotely sensed ocean color to characterize the ultraviolet (UV) radiation field in surface water along with quantitative chemical data for the photochemical efficiency of H2O2 formation. Wavelength- and temperature-dependent efficiency (i.e., apparent quantum yield, AQY) spectra previously reported for a variety of seawater sources, including coastal and oligotrophic stations in Antarctica, the Pacific Ocean at Station ALOHA, the Gulf of Mexico, and several sites along the eastern coast of the United States were compiled to obtain a “marine-average” AQY spectrum. To evaluate our predictions of H2O2 photoproduction in surface waters using this single AQY spectrum, we compared modeled rates to new measured rates from Gulf Stream, coastal, and nearshore river-outflow stations in the South Atlantic Bight, GA, United States; obtaining comparative differences of 33% or less. In our global model, the “marine-average” AQY spectrum was used with modeled solar irradiance, together with satellite-derived surface seawater temperature and UV optical properties, including diffuse attenuation coefficients and dissolved organic matter absorption coefficients estimated with remote sensing-based algorithms. The final product of the model, a monthly climatology of depth-resolved H2O2 photoproduction rates in the surface mixed layer, is reported for the first time and provides an integrated global estimate of ∼21.1 Tmol yr−1 for photochemical H2O2 production. This work has important implications for photo-redox reactions in seawater and improves our understanding of the role of solar irradiation on ROS cycling and the overall oxidation state in the oceans.
利用遥感海洋颜色在全球海洋中深度分辨过氧化氢的光化学生产
过氧化氢(H2O2)是天然水体中一种重要的活性氧(ROS),通过参与金属氧化还原反应影响水质,对海洋生态系统造成氧化应激。虽然人们已经尝试更好地了解全球海洋中H2O2的动态,但各种H2O2来源和损失的相对重要性仍然不确定。我们的模型通过利用遥感海洋颜色来表征地表水中的紫外线辐射场以及H2O2形成光化学效率的定量化学数据,改进了以前对光化学H2O2产率的估计。对以前报道的各种海水来源的波长和温度依赖的效率(即表观量子产率,AQY)光谱进行了汇编,以获得“海洋平均”AQY光谱,这些海水来源包括南极洲的沿海和寡营养站、太平洋的ALOHA站、墨西哥湾和美国东海岸的几个站点。为了评估我们使用单一AQY光谱对地表水中H2O2光产生的预测,我们将模型速率与来自美国乔治亚州南大西洋湾湾湾流、沿海和近岸河流流出站的新测量速率进行了比较;获得33%或更少的比较差异。在我们的全球模型中,“海洋平均”AQY光谱与模拟的太阳辐照度、卫星导出的表面海水温度和紫外线光学特性(包括散射衰减系数和基于遥感算法估计的溶解有机质吸收系数)一起使用。该模式的最终产品,即表层混合层深度分辨H2O2光产生速率的月度气气学,首次被报道,并提供了光化学H2O2产生的综合全球估计为~ 21.1 Tmol yr−1。这项工作对海水中的光氧化还原反应具有重要意义,并提高了我们对太阳照射对海洋中ROS循环和整体氧化状态的作用的理解。
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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