美国西北太平洋地区大气水中氘过量和17o过量变化

J. Bershaw, D. Hansen, A. Schauer
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引用次数: 32

摘要

水的高精度三氧同位素分析产生了一个新的二阶参数,17O-excess(通常表示为Δ17O),它描述了δ18O和Δ17O之间参考关系的偏差。这种示踪剂与氘过量(d-过量)一样,在水文循环的相变过程中受到动力学分馏(扩散)的影响。然而,与d过量不同的是,17o过量存在于古水代用矿物中,并且被认为不随温度发生显著变化。这使得它成为古气候研究中很有前途的工具,特别是在传统方法产生模棱两可结果的相对干旱的大陆地区。本文利用太平洋西北部两条东西样带的新δ18O、δ17O和δ2H数据,探讨了17o过量对地形、气候和湿气源的敏感性。我们发现奥运山和海岸山脉之间d-excess和17O-excess的差异与不同的水汽源气象是一致的,这是由气团反轨迹分析推断出来的。水汽d过量受海源相对湿度和温度的影响,而水汽17o过量受海源相对湿度的控制。与d-excess一样,17O-excess也受到喀斯喀特山脉雨影蒸发的显著影响,这支持了它在没有δ2H数据的古气候研究中作为干旱指标的实用性。我们利用雨滴蒸发模式和当地气象学研究了云下蒸发对沿高度样带的d-excess和17O-excess的影响。我们发现,云下蒸发在很大程度上解释了观测到的d-excess随海拔升高的增加,但不是全部,在俄勒冈州的奥林匹克山脉和海岸山脉有少量的17O-excess变化。17O-excess在空间上与太平洋西北部的相对湿度相关,支持其在古气候研究中作为干旱指标的使用。奥林匹克山脉和俄勒冈海岸山脉之间d-excess和17O-excess的差异表明它们的水分来源不同。云下蒸发解释了观测到的d-excess随海拔升高而增加的大部分原因,以及奥林匹克山脉和俄勒冈海岸山脉少量的17O-excess变化。
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Deuterium excess and 17O-excess variability in meteoric water across the Pacific Northwest, USA
Abstract High-precision triple oxygen isotope analysis of water has given rise to a novel second-order parameter, 17O-excess (often denoted as Δ17O), which describes the deviation from a reference relationship between δ18O and δ17O. This tracer, like deuterium excess (d-excess), is affected by kinetic fractionation (diffusion) during phase changes within the hydrologic cycle. However, unlike d-excess, 17O-excess is present in paleowater proxy minerals and is not thought to vary significantly with temperature. This makes it a promising tool in paleoclimate research, particularly in relatively arid continental regions where traditional approaches have produced equivocal results. We present new δ18O, δ17O, and δ2H data from stream waters along two east–west transects in the Pacific Northwest to explore the sensitivity of 17O-excess to topography, climate, and moisture source. We find that discrepancies in d-excess and 17O-excess between the Olympic Mountains and Coast Range are consistent with distinct moisture source meteorology, inferred from air-mass back trajectory analysis. We suggest that vapor d-excess is affected by relative humidity and temperature at its oceanic source, whereas 17O-excess vapor is controlled by relative humidity at its oceanic source. Like d-excess, 17O-excess is significantly affected by evaporation in the rain shadow of the Cascade Mountains, supporting its utility as an aridity indicator in paleoclimate studies where δ2H data are unavailable. We use a raindrop evaporation model and local meteorology to investigate the effects of subcloud evaporation on d-excess and 17O-excess along altitudinal transects. We find that subcloud evaporation explains much, but not all of observed increases in d-excess with elevation and a minor amount of 17O-excess variation in the Olympic Mountains and Coast Range of Oregon. Key Points 17O-excess correlates spatially with relative humidity across the Pacific Northwest, supporting its use as an aridity indicator in paleoclimate studies. Discrepancies in d-excess and 17O-excess between the Olympic Mountains and Oregon Coast Range suggest that their moisture source is different. Subcloud evaporation explains most of observed increases in d-excess with elevation, and a minor amount of 17O-excess variation in the Olympic Mountains and Oregon Coast Range.
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