Sai Louie, AJMorgan, LKBanks, EWDempsey, DWilson, S2024-11-282023-11-042023-122023-10-302352-3409AN4R7 (isidoc)38020435 (pubmed)https://hdl.handle.net/10182/17879Braided rivers play a significant role in replenishing groundwater, but our understanding of how these recharge rates fluctuate over time remains limited. Traditional techniques for gauging groundwater recharge are ineffective for studying complex braided river systems due to their insufficient spatiotemporal resolution. To address this gap, active-distributed temperature sensing (A-DTS) was used. This method combines fiber optic temperature measurements with an active heat source, enabling quantification of groundwater fluxes. In this study, twelve consecutive A-DTS surveys were conducted on a 100 m long hybrid fiber optic cable to a depth of 5 m beneath the Waikirikiri Selwyn River. This experiment was conducted during a period of relatively stable river stage and flow, highlighting the effectiveness of using A-DTS to measure temporal changes in groundwater recharge.6 pagesElectronic-eCollectionen© 2023 The Author(s). Published by Elsevier Inc.alluvial aquiferfiber opticsgroundwater rechargeheat as a tracerriverActive-distributed temperature sensing dataset beneath a braided riverJournal Article10.1016/j.dib.2023.1097562352-3409ANZSRC::370703 Groundwater hydrologyANZSRC::370704 Surface water hydrologyANZSRC::410503 Groundwater quality processes and contaminated land assessmenthttps://creativecommons.org/licenses/by/4.0/Attribution