Carbon evolution and mixing effects on groundwater age calculations in fractured basalt, southwestern Idaho, U.S.A.

IF 2.6 Q2 WATER RESOURCES
Melissa Schlegel, Jennifer Souza, S. Warix, Erin M. Murray, S. Godsey, M. Seyfried, Zane K. Cram, K. Lohse
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Abstract

Using hydrochemical and isotopic compositions of springs and wells, we trace carbon from critical zone carbon dioxide (CO2) into groundwater of the semi-arid Reynolds Creek Experimental Watershed - Critical Zone Observatory, southwestern Idaho, USA. Dissolved inorganic carbon (DIC) concentrations, pH and stable isotope tracers of carbon for DIC (δ13CDIC), are used to show that most groundwater evolves under open system conditions, moving carbon into the groundwater and acting as a carbon sink. However, one sample (−10.94‰ δ13CDIC, 6,350 14C years before present (yrs. BP)) may have evolved under closed system conditions with a higher partial pressure of critical zone CO2 than present-day soils. By characterizing the carbon cycle, we show that (1) carbon evolution is primarily under open-system conditions, (2) shallow groundwater samples are generally less mixed and more recent (10 to 70 3H yrs. BP) than deeper groundwater samples (1,469 to 6,350 14C yrs. BP), and (3) the older portion of the groundwater may be even older than the calculated 14C ages, as indicated by the mixing of age tracers in intermediate wells. Our global conception of the deep critical zone should include carbon cycling of critical zone CO2 in old groundwater. Characterizing the deep critical zone in a semi-arid weathered silicate watershed improves our global understanding of carbon, nutrient and water cycling.
美国爱达荷州西南部断裂玄武岩中碳演化和混合对地下水年龄计算的影响
利用泉水和水井的水化学和同位素组成,我们追踪了从临界区二氧化碳(CO2)进入美国爱达荷州西南部半干旱雷诺兹溪实验流域--临界区观测站地下水的碳。溶解无机碳(DIC)浓度、pH 值和 DIC 碳的稳定同位素示踪剂(δ13CDIC)被用来表明大多数地下水在开放系统条件下演化,将碳带入地下水并成为碳汇。然而,有一个样本(-10.94‰ δ13CDIC,距今 6,350 14C 年)可能是在封闭系统条件下演化的,临界区二氧化碳分压高于现今土壤。通过分析碳循环的特征,我们发现:(1) 碳的演化主要是在开放系统条件下进行的;(2) 浅层地下水样本通常比深层地下水样本(1,469 至 6,350 14C 年前)混合程度更低、年代更早(10 至 70 3H 年前);(3) 正如中间井中年代示踪剂的混合情况所表明的,地下水的较老部分可能比计算出的 14C 年代还要早。我们对深临界区的总体概念应包括临界区老地下水中二氧化碳的碳循环。描述半干旱风化硅酸盐流域深临界区的特征,可以提高我们对碳、养分和水循环的全球认识。
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来源期刊
Frontiers in Water
Frontiers in Water WATER RESOURCES-
CiteScore
4.00
自引率
6.90%
发文量
224
审稿时长
13 weeks
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