The cumulative and bidirectional groundwater-surface water (GW-SW) interaction along a stream is defined as hydrological turnover (HT) influencing solute transport and source water composition. However, HT proves to be highly variable, producing spatial exchange patterns influenced by local surface- and groundwater levels, geology and topography. Hence, identifying factors controlling HT in streams poses a challenge. We studied the spatiotemporal variability of HT processes at a third order tributary of the river Mosel, Germany at two different stream reaches over a period of two years. Additionally, we sampled for silicate concentrations in the stream as well as in the near-stream groundwater. Thus, creating snapshots of the boundary layer between ground- and surface water where turnover induced mixing occurs. We characterize reach specific drainage behavior by utilizing a delayed/base flow separation analysis for both reaches. The results show a site-specific negative correlation of HT with discharge, while hydraulic gradients and reach scale absolute discharge changes correlating with HT only at the upstream site which is characterized by steeper hillslopes compared to the downstream section. Analyzing the variation of silicate concentrations between stream and wells shows that in-reach silicate variation increases significantly with the decrease of HT under groundwater dominated flow conditions.. In Summary, our results show that discharge shapes the influence of HT on solute transport as visualized by silicate variations. Yet, reach specific drainage behavior shapes seasonal states of groundwater storages and thus, can be an additional control of HT magnitudes, influencing physical stream water composition throughout the year.

Direction and depths of hyporheic exchange fluxes at the groundwater - surface water interface are drivers of biogeochemical processes influencing nutrient cycling and water quality. Model concepts on the dynamic relationship between hyporheic exchange fluxes and exchange depth are typically based on the assumption of a linear relationship between both measures. Here, we quantify seasonal and episodic variations of hyporheic exchange fluxes and hyporheic exchange depths with methods of heat tracing. Numerically (FLUX-BOT) and analytically (VFLUX; method based on temperature amplitude dampening developed by Hatch et al., 2006) working program scripts were used to solve the one-dimensional conduction-advection-dispersion equation and compute hyporheic flux rates from three vertical sediment water temperature profiles recorded continuously in a small low mountain creek between 2011 and 2017. By comparing the behavior of two differing water temperature-based modelling approaches, dissimilarities in the sensitivity to sediment thermal properties were identified. These differences in parameter responsivity explain deviating behavior of the models regarding exchange flux and depth calculations. We show that the vertical extension of hyporheic exchange depth has a distinctive seasonal pattern over seven years, which differs between the chosen models. Surface water levels, groundwater levels and stream discharges show significant correlations with both flux direction and hyporheic zone extension. In contrast to the numerical modelling approach, analytically derived flux data allowed for establishing a significant relationship between the hydraulic gradient observed at a nearby groundwater well and simulated hyporheic exchange depths.