Singley, Joel GÌý1Ìý;ÌýWlostowski, Adam NÌý2Ìý;ÌýBergstrom, Anna JÌý3Ìý;ÌýSokol, Erick RÌý4Ìý;ÌýTorrens, Christa LÌý5Ìý;ÌýJaros, ChrisÌý6Ìý;ÌýWilson, Colleen EÌý7Ìý;ÌýGooseff, Michael NÌý8
1ÌýEnvironmental Studies Program, Â鶹ӰԺ
2ÌýDepartment of Civil, Environmental, and Architectural Engineering, Â鶹ӰԺ
3ÌýDepartment of Geological Sciences, Â鶹ӰԺ
4ÌýInstitute of Arctic and Alpine Research, Â鶹ӰԺ
5ÌýEnvironmental Studies Program, Â鶹ӰԺ
6ÌýInstitute of Arctic and Alpine Research, Â鶹ӰԺ
7ÌýDepartment of Civil, Environmental, and Architectural Engineering, Â鶹ӰԺ
8ÌýDepartment of Civil, Environmental, and Architectural Engineering, Â鶹ӰԺ
The analysis of concentration-discharge (C-Q) relationships has often been used in an inverse modeling framework to quantify source water contributions and biogeochemical processes occurring within catchments, especially during discrete hydrological events. Yet, the interpretation of C-Q hysteresis is often confounded by catchment complexity, such as a large number of source waters and non-stationarity in their hydrochemical composition. Attempts to overcome these challenges often necessitate ignoring or lumping together potentially important runoff pathways and geochemical sources/sinks. This is especially true of the hyporheic zone because it acts as an integrator of multiple sources and typically lacks a unique hydrochemical signature. Furthermore, these complexities often limit efforts to identify catchment processes responsible for the transience of C-Q hysteresis between discrete hydrological events. To address these challenges, we leverage the hydrologic simplicity and long-term, high frequency Q and electrical conductivity (EC) data from streams in the McMurdo Dry Valleys, Antarctica. In this two end-member system, EC can serve as a proxy for the concentration of solutes derived from the hyporheic zone and reveal the legacy of mixing processes occurring along the stream. We utilize a novel approach to decompose loops into sub-hysteretic EC-Q dynamics in order to identify individual mechanisms governing hysteretic patterns and transience across a wide range of timescales. From this analysis, we find that hydrologic and hydraulic processes govern EC response to diel and seasonal Q variability resulting in discrete hysteretic behavior. We also observe that variable hyporheic turnover rates govern EC-Q patterns at daily, annual, and interannual timescales and contribute differently to transient hysteresis in short and long streams. The framework we utilize to analyze sub-hysteretic dynamics may be applied more broadly to constrain the processes controlling C-Q transience and aid advancements in understanding the evolution of catchment processes and structure over time.