Connecting diverse disciplines to improve understanding of surface water-groundwater interactions

IF 3.1 Q2 GEOSCIENCES, MULTIDISCIPLINARY
Sarah H. Ledford , Martin Briggs , Robin Glas , Margaret A. Zimmer
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引用次数: 2

Abstract

Laura K. Lautz is a premier mentor, collaborator, and researcher at the intersection of natural hydrologic systems and humans. Her research has shifted the paradigm around measuring and understanding the impacts of surface water and groundwater interactions across spatial and temporal scales. She has done this by testing and refining new methods and by collaborating with, training, supporting, and mentoring diverse scientists. Here, we review her research across five themes, summarizing the prior status of the field, what Lautz contributed, as well as new directions in the field inspired by her work. Lautz’s research expanded our understanding of the impacts of stream restoration on surface water-groundwater interactions, where she tested new field methods and showed that restoration structures increase hyporheic exchange, locally altering biogeochemical function of the streambed. She refined novel methods for measuring surface water-groundwater exchanges and worked to make these methods easily accessible through freely available software. Her research group greatly expanded the use of heat as a quantitative tracer of hydrologic processes via the well-used VFLUX and HFLUX programs. Her research evaluated the impacts of surface water-groundwater interactions in urban streams, showing the substantial fluxes of nutrients and chloride that can move through those exchanges and the potential for groundwater to help buffer contamination. To assess groundwater impacts on streamflow below tropical glaciers, she used a wide range of field methods to reveal the sensitivity of these systems to climate change. Finally, she built tools to quantify natural brine contamination of drinking water wells in areas that may later be subject to high-volume hydraulic fracturing, creating a needed ‘pre-fracking’ dataset. Through this process, she identified multiple sources of salinity that are already reaching wells in these systems. Overall, this research has been done with a focus on mentoring and training the next generation of hydrologists, including work to specifically train for careers beyond academia, and facilitating early career scientists to realize their innate potentials. With former trainees in careers across industry, government, and academia, Dr. Laura K. Lautz is now working to build cross-disciplinary research at even larger scales, across federal research units, guaranteeing that an even larger impact on hydrology is still to come.

连接不同的学科,以提高对地表水-地下水相互作用的理解
劳拉·劳茨是自然水文系统与人类交叉领域的首要导师、合作者和研究员。她的研究改变了测量和理解地表水和地下水相互作用在空间和时间尺度上的影响的范式。她通过测试和改进新方法以及与不同的科学家合作、培训、支持和指导来做到这一点。在这里,我们回顾了她在五个主题上的研究,总结了该领域的先前状态,劳茨的贡献,以及受她的工作启发的领域的新方向。劳茨的研究扩展了我们对河流恢复对地表水-地下水相互作用影响的理解,在那里她测试了新的现场方法,并表明恢复结构增加了地下交换,局部改变了河床的生物地球化学功能。她改进了测量地表水-地下水交换的新方法,并致力于通过免费软件使这些方法易于获取。她的研究小组通过广泛使用的VFLUX和HFLUX程序,极大地扩展了热作为水文过程定量示踪剂的使用。她的研究评估了地表水和地下水在城市河流中的相互作用的影响,显示了大量的营养物质和氯化物可以通过这些交换流动,以及地下水帮助缓冲污染的潜力。为了评估地下水对热带冰川下水流的影响,她使用了广泛的实地方法来揭示这些系统对气候变化的敏感性。最后,她建立了工具来量化未来可能进行大规模水力压裂的地区饮用水井的天然盐水污染,创建了所需的“水力压裂前”数据集。通过这一过程,她确定了这些系统中已经进入油井的多种盐度来源。总的来说,这项研究的重点是指导和培训下一代水文学家,包括为学术界以外的职业进行专门培训的工作,并促进早期职业科学家发挥他们的内在潜力。劳拉·k·劳茨(Laura K. Lautz)博士以前的受训者在工业、政府和学术界从事职业,现在正致力于在更大的范围内建立跨学科研究,跨越联邦研究单位,确保对水文学产生更大的影响。
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
Journal of Hydrology X
Journal of Hydrology X Environmental Science-Water Science and Technology
CiteScore
7.00
自引率
2.50%
发文量
20
审稿时长
25 weeks
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