Major ion pore-water chemistry evolution in Lake Michigan benthic sediments: Evidence for direct input from Michigan Basin saline groundwater

Jonathan J. Kolak, David T. Long
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Abstract

The Michigan Basin is composed of geological formations that contain brines and evaporites, and solutes from these geological sources have affected benthic sediment pore-water chemistry in Saginaw Bay (Lake Huron). We hypothesize that there exists similar potential for upward solute transport directly from the Michigan Basin into other Great Lakes areas. To test our hypothesis, we present here previously unpublished pore-water chemistry analyses from sediment cores collected during multiple Lake Michigan sampling events (spanning 1991−1999) and a new evaluation of previously published data. In several box cores, pore-water chloride concentrations increase with depth, and Cl:Br ratios are consistent with a geological formation brine source. In all gravity cores we collected from southern Lake Michigan, pore-water sodium concentrations increase with sediment depth. At one sample station, pore-water sodium concentrations exceed 2000 mg L−1 within 2 m of the sediment-water interface. Given the pore-water chemistry changes reported here, combined with information from previous studies of Lake Michigan bedrock geology, a Devonian formation brine is a plausible solute source. The presence of saline pore water within glaciolacustrine sediments underlying Lake Michigan indicates that this solute flux has been active during the past 10 k.y. However, the origins of this solute flux, including timing (onset) and contributions from advective and/or diffusive transport, are unknown. The specific geological source and solute transport process are important to resolve in order to evaluate potential effects of these Michigan Basin solute sources on the Great Lakes’ sediment biogeochemistry and water quality.
密歇根湖底栖沉积物中主要离子孔隙水化学演变:密歇根盆地含盐地下水直接输入的证据
密歇根盆地由含有卤水和蒸发岩的地质构造组成,这些地质来源的溶质影响了萨吉诺湾(休伦湖)底栖沉积物孔隙水的化学性质。我们推测,从密歇根盆地直接向五大湖其他地区的溶质上溯迁移也存在类似的可能性。为了验证我们的假设,我们在此展示了之前未发表的、在密歇根湖多次取样活动(时间跨度为 1991-1999 年)中收集的沉积物岩心的孔隙水化学分析结果,以及对之前已发表数据的新评估。在几个箱形岩心中,孔隙水氯化物浓度随深度增加而增加,Cl:Br 比值与地质形成的盐水源一致。在我们从密歇根湖南部采集的所有重力岩心中,孔隙水钠浓度随着沉积深度的增加而增加。在一个取样站,沉积物-水界面 2 米范围内的孔隙水钠浓度超过 2000 毫克/升。鉴于此处报告的孔隙水化学变化,结合之前对密歇根湖基岩地质的研究信息,泥盆纪形成的盐水是一个可信的溶质来源。密歇根湖下冰川岩屑沉积物中存在的含盐孔隙水表明,这种溶质通量在过去 10 千年中一直很活跃。然而,这种溶质通量的来源,包括时间(开始时间)以及平流和/或扩散输运的贡献,尚不清楚。要评估这些密歇根盆地溶质源对五大湖沉积物生物地球化学和水质的潜在影响,就必须解决具体的地质来源和溶质迁移过程问题。
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