Kirchner (2016a) designed the young water fraction as the proportion of the transit time distribution younger than a threshold age (τyw). By assuming that the transit time distribution mathematical form is the regularized lower incomplete gamma function for all the study catchments, the theoretical young water fraction (FywT) can be expressed as 2FywT=Pτ<τyw=∫0τywτα-1βαΓ(α)e-τβdτ, where α and β are the shape and scale factor, respectively.

By using thought experiments, Kirchner (2016a) has demonstrated that for a given shape factor α (ranging from 0.2 to 2) and across a wide range of scale factors β, the theoretical young water fraction can be accurately predicted by the amplitude ratios of seasonal sine curves fitted to stream water and precipitation isotope values by considering a τyw of 2–3 months. Operatively, we model seasonal isotope (e.g., δ18O) cycles in stream water and precipitation as reported in Eqs. (3a) and (3b): 3aδ18OS(t)=ASsin⁡2πft-φS+kS,3bδ18OP(t)=APsin⁡2πft-φP+kP, where δ18O (‰) is the isotopic composition of water sampled at the time t (expressed in decimal years), A (‰) is the amplitude of the seasonal isotope cycle, φ (in radians, with 2π rad = 1 year) is the phase, f (yr-1) is the frequency and k (‰) is the vertical offset of the seasonal isotope cycle. The subscript S refers to stream water, while the subscript P refers to precipitation. The sine wave is fitted to the isotopes measured in precipitation weighted according to the volume of precipitation, reducing the influence of low-precipitation periods and accounting for temporally aggregated rainfall samples (von Freyberg et al., 2018); the sine fit of stream water isotope measurements can be discharge-weighted, using the discharge measured at the moment of sampling as weights, or not (von Freyberg et al., 2018). The sine curves of Eqs. (3a) and (3b) are fitted on the isotope measurements using the iteratively re-weighted least squares (IRLS) method (for reducing the influence of outliers), which leads to estimates of A, φ and k parameters. A function for performing a sine fit using IRLS, based on the IRLS function made available by Kirchner and Knapp (2020), is available in the Supplement.

Accordingly, depending on the unweighted or the flow-weighted fit, an unweighted amplitude (AS) or a flow-weighted amplitude (AS*) can be obtained, respectively. Such amplitudes can be used to calculate the time-weighted (Eq. 4a) or the flow-weighted (Eq. 4b) young water fractions (Fyw or Fyw*, respectively) via the “amplitude ratio approach”: 4aFyw=ASAP,4bFyw*=AS*AP. Gallart et al. (2020a) highlighted the advantages of the flow-weighted analysis (generally yielding AS* greater than AS) to compensate for subsampled high-flow periods, which would otherwise lead to a young water fraction underestimate. Accordingly, in this work, we calculate the flow-weighted young water fractions for all the study catchments by applying Eq. (4b). We obtain the standard errors (SEFyw*) of the estimated Fyw* using Eq. (5): 5SEFyw*=1APSEAS*2+AS*AP2⋅SEAP2, where SEAS* and SEAP are the standard errors of the regression coefficients AS* and AP. The analytical choice of using the amplitude (AP) fitted to precipitation isotopes, instead of the amplitude (APeq) fitted to the equivalent precipitation (i.e., rain plus snowmelt) isotopes, for estimating Fyw* implies that the snowpack (and/or the glacier) is considered as part of the catchment storage. Thus, the damped seasonal cycle observed in the stream is given by the mixing of precipitation with snowpack (and/or the glacier) and subsurface storage (the last two considered as a single entity), as illustrated in Fig. 4.

Since we have assumed that the transit time distribution belongs to the family of gamma distributions, we can determine the parameter α of such a distribution by solving the following implicit expression for α (Eq. 6): 6φS*-φP=αarctan⁡AS*/AP-2α-1. We optimized to find the best solution of Eq. (6) using the best-fitting parameters (φS*, φP, AS*, AP) with α spanning a wide interval between 0.01 and 20. For the relevant math, the reader is referred to Kirchner (2016a). We estimate the uncertainty of α assuming all the fitted parameters having a Gaussian distribution with a standard deviation equal to the regression error (Eqs. 3a and 3b). We generate 1000 random samples of such parameters, and we estimate the optimal α for each parameter set and then compute their standard deviation.

As in past studies (Gallart et al., 2020a; Lutz et al., 2018), we use the parameter α to estimate τyw with the following second-order polynomial fit (Kirchner, 2016a): 7τywT≈0.0949+0.1065α-0.0126α2, where T is the period of the tracer cycle (for a seasonal cycle, T=1 year). We estimate the uncertainty of τyw by calculating the standard deviation of the threshold ages computed using the 1000 optimal α values previously obtained. A code for estimating α and τyw with their uncertainties is made available in the Supplement.

The comparison of Fyw* among different catchments is potentially subject to a bias given by possibly different threshold ages ranging between 2 and 3 months. Accordingly, we couple each Fyw* with the corresponding τyw to illustrate what the term “young” means for each study catchment.

In this paper, we quantify the snowpack persistence by calculating the mean fractional snow cover area (FSCA). It is calculated for each catchment over the period 1 October 2017–30 September 2021 (hereafter defined as PoC, i.e., period of calculation) by using the collection of Sentinel-2 L2A satellite images available in Google Earth Engine (Gorelick et al., 2017). Temporally, this relatively recent satellite has increased the visitation frequency to a subweekly temporal resolution and increased the spatial resolution to 20 m for snow cover (Gascoin et al., 2019). High temporal resolution makes Sentinel-2 images preferable to Landsat images, which are available only once every 16 d and whose total number is often further reduced because of cloudiness (Hofmeister et al., 2022). The PoC generally differs from the PoS for the 27 study catchments. This is because Sentinel-2 L2A satellite images are not available before March 2017. For each image available in the PoC, we calculate the normalized difference snow index (NDSI) as suggested in the work of Dozier (1989): 8NDSI=rgreen-rSWIRrgreen+rSWIR, where rgreen is the reflectance in the green band (Sentinel-2 band 3) and rSWIR is the shortwave infrared reflectance band (Sentinel-2 band 11). We classify as snowy pixels those with an NDSI value > 0.4 (Dozier, 1989). Based on the pixel-by-pixel snow classification, we compute the snapshot fractional snow cover area (fSCA) according to Di Marco et al. (2020) and Hofmeister et al. (2022): 9fSCA=NsnowNtot-Nclouds, where Nsnow is the number of snow cover pixels according to the applied NDSI threshold method, Ntot is the total number of pixels within the catchment area and Ncloudsis the number of pixels classified as clouds and water bodies (Hofmeister et al., 2022). We identify the cloudy pixels directly using the Sentinel-2 band “Scene Classification Map”. We operatively calculate Nsnow, Ntot and Nclouds using a Google Earth Engine code.

By using this procedure for calculating fSCA, we sometimes obtain fSCA>1. The NDSI threshold method is generally able to distinguish between snow and no-snow pixels (Aalstad et al., 2020). Accordingly, clouds and snow have similar reflectance in the green band, but clouds highly reflect in the shortwave infrared band, while snow reflectance is low in this band. Thus, the Nsnow estimation is generally accurate. On the other hand, it is necessary to disregard the false positive pixels deriving from cloud detection (i.e., snow classified as clouds). If fSCA>1, we calculate fSCA as Nsnow/Ntot, since this is the only heuristic solution that guarantees no overestimation. Moreover, by looking at sample Sentinel-2 images during the summer periods for all the catchments, we impose fSCA=0 during July and August, since when fSCA≠0, this usually results from clouds falsely identified as snow: imposing fSCA=0 clearly leads to fewer errors (only missing occasional summer snowfall events of very shallow depth) than falsely accounting for (far more) frequent clouds. The NBPV catchment is an exception: we do not impose fSCA=0 during July and August, since it generally has snow over the glacier also during summer. Finally, we compute the mean fractional snow cover area (FSCA) for each catchment by averaging all fSCA values available for all snow images in the PoC, without interpolation between the time steps.

Similarly to Arnoux et al. (2021), we calculate the portion of the catchment area occupied by Quaternary deposits (Aqd) (available from government geological data sets) with respect to the total catchment area (A). Thus, we calculate the fraction of Quaternary deposits (Fqd) as reported by Eq. (10): 10Fqd=AqdA. Additionally, we use the same winter flow index (WFI) as Arnoux et al. (2021), as indicated by Eq. (11): 11WFI=QNM7Qmean, where QNM7 is the minimum discharge over 7 consecutive days during the winter period (from November to June) and Qmean is the mean annual discharge. We calculate it for the 27 study catchments during the PoS. To relate WFI to low flow, we apply the recent baseflow separation technique described by Duncan (2019) to the discharge time series of the 27 study catchments (within the PoS indicated in Table 1). In short, this method comprises a single backward pass through the data to fit an exponential master baseflow recession curve (Eq. 12a), followed by the single forward pass (Eqs. 12b and 12c) of the Lyne and Hollick (1979) algorithm. This allows the smoothing of the connection between segments of the master recession by simulating a gradual groundwater recharge during the runoff event (Duncan, 2019): 12aMti-1=Mti-ck+c12bQqti=kQqti-1+Mti-Mti-11+k212cQbfti=Mti-Qqti, where M(ti), Qq(ti) and Qbf(ti) are the master recession value, the quick recession flow and the baseflow at time ti, respectively. In this study, we consider daily time steps (i.e., ti-ti-1=1 d). This method has two parameters: k is the recession constant, c is a constant flow added to the exponential decay component. We set the recession constant k=0.925 (Nathan and McMahon, 1990): we add no constant flow to the exponential decay (i.e., in terms of the method by Duncan (2019), c=0). A code with the implementation of the Duncan (2019) baseflow filter has been made available in the Supplement.

To express the catchment storage contribution to streamflow in a form that is directly comparable to the Fyw*, we define the baseflow fraction (Fbf) as reported in Eq. (13): 13Fbf=1n∑i=1nQbftiQti, where Qbf(ti) is the baseflow (mm d-1) at the time ti (obtained as indicated by Eq. 12c) and Q(ti) is the discharge (mm d-1) at the time ti. We tested the uncertainty of k by drawing random samples (10 000) from a normal distribution spanning Nathan and McMahon's (1990) recommended range for k from 0.90 to 0.95, with a mean of 0.925 and a standard deviation equal to 25 % of the range. Thereby, we obtain 10 000 values of Fbf for each catchment of which we compute the standard deviation.

As introduced in Sect. 1, Fyw* can be low if the snapshot young water fraction Fyw(ti) is very low for many time steps. If we consider the discharge (Q) as a proxy for the catchment wetness, we can reliably assert that Fyw(ti) is low for low Q(ti). Thus, another important variable is the duration of the low-flow period. In this study, we define a low-flow period (TLow) as follows: 14TLow=∀ti:QbftiQti≥0.85. Thus, a low-flow period is defined here as a period when 85 % of the total flow is composed of baseflow (i.e., baseflow dominated). Accordingly, we define the low-flow duration (LFD) as the proportion of the time steps (e.g., days) in the PoS that can be considered as a low-flow period according to Eq. (14).

Assembling Fyw* values determined by different authors who very likely used different source codes could possibly result in a bias. Indeed, differences in Fyw* among catchments could be driven by the different methods rather than the physical factors. Therefore, the same approach must be applied to all the study catchments to remove the bias introduced by the estimation method of Fyw*. For all the study catchments, sinusoidal cycles were fitted to both precipitation and stream water δ18O data by using the IRLS regression (results for six representative study catchments in Fig. 5; complete results in Fig. S2). We estimate Fyw* via Eq. (4b) by using the best-fitting amplitudes of seasonal cycles. The best-fit amplitudes (AP, AS*), phases (φP, φS*) and corresponding standard errors are reported in Table 2.

The Fyw* values achieved in this study are consistent with published Fyw* values of Ceperley et al. (2020) and with direct-input Fyw* of von Freyberg et al. (2018). Accordingly, a two-sample Kolmogorov–Smirnov test accepts the null hypothesis that the new and past Fyw* estimates are from the same continuous distribution at the 5 % significance level. The Fyw* estimates are reported in Fig. 6a against the mean catchment elevation and are also listed in Table 2. Fyw* increases with mean catchment elevation until 1500 m a.s.l., which corresponds to the elevation above which all catchments are snow dominated (with NBPV detected as an outlier as will be discussed in Sect. 4.5). This pattern is also reflected by the median Fyw* within each flow regime: the median Fyw* is 0.13 for rainfall-dominated catchments, 0.29 for hybrid catchments and 0.12 for snow-dominated catchments. Such results are consistent with previous studies that have shown the tendency toward low Fyw* in mountainous catchments (Ceperley et al., 2020; von Freyberg et al., 2018; Lutz et al., 2018; Jasechko et al., 2016).

Even though we remove the bias introduced by the estimation method of Fyw*, the application of Eq. (4b) implicitly introduces another bias if we want to use Fyw* for intercomparison purposes (which is the goal of this work). By computing the amplitude ratio, we estimate FywT (Eq. 2), without defining a corresponding τyw (which can be estimated via Eq. 7). Therefore, part of the scatter of Fyw* between catchments might be because of different τyw rather than physical factors, also if the τyw is expected to vary modestly between 2 and 3 months (Kirchner, 2016a). Accordingly, past studies estimated Fyw* using the amplitude ratio approach without information about the corresponding τyw (Stockinger et al., 2019; von Freyberg et al., 2018; Jasechko et al., 2016). Nevertheless, we estimate τyw and α for each study catchment: the resulting estimates are reported in Fig. 6b and are listed in Table 2. Our estimates of the α parameter (0.19≤α≤2.1) are consistent with the shape factor range (0.2≤α≤2) investigated by Kirchner (2016a). Consequently, the τyw obtained by applying Eq. (7) falls between 1.38 and 3.16 months. As expected, τywvaries in a narrow range consistent with the explanation provided by Kirchner (2016a). However, in order to have a fully coherent metric for all the catchments, the optimal procedure would be to set τyw and to calculate the young water fraction corresponding to this τyw. Nevertheless, establishing a constant τyw for all the catchments could be a tricky choice. Indeed, by setting a τyw higher than that obtained via Eq. (7), we are improperly using the TTD to estimate the young water fraction. From this reasoning, the only solution is to set τyw equal to the overall minimum τyw. This choice ensures that the TTD is used properly to estimate the young water fraction in all the sites. What we could expect is that all the young water fractions would be lower with respect to those obtained with the amplitude ratio approach. However, changes in young water fraction depending on changes in τyw are unintuitive, since they vary with the TTD shape. Accordingly, a constant reduction of τyw would change the area under the transit time pdf differently based on the α value. Thus, the overall effect of the reduced τyw upon the young water fraction remains a priori unknown.

Since in this study we are using the amplitude ratio approach, our Fyw* estimates refer to the proportion of runoff younger than an inconsistent threshold age. This variation by catchment (albeit limited) is the main limitation of this work.

In line with the results of Arnoux et al. (2021), we find a negative statistically significant correlation between Fyw* and WFI (ρSpearman=-0.5, p value < 0.01; see Fig. S6), suggesting (unsurprisingly) that more groundwater contribution to streamflow increases the water age. WFI and Fqd values for all the study catchments are reported in Table 2. To analyze the relationship of Fyw* with Quaternary deposits, we exclude the SOU and BCC catchments, since they show Fqd=0 (see Table 2). The inclusion of catchments with Fqd=0 would bias the analysis, since an absent parameter cannot modulate the share of groundwater and thus the young water fraction in the stream.

By focusing first only on the snow-dominated catchments, a linear fit on the data returns a negative slope of -0.36 (R2=0.52), indicating a reduction of Fyw* with increasing Fqd (Fig. 7a). Moreover, we find a Spearman rank correlation coefficient of -0.6 with a p value of 0.13, meaning a negative but not statistically significant correlation between Fyw* and Fqd. This result can be explained by considering several factors. First, water storage in Quaternary deposits is not the only groundwater storage contribution to the stream in such environments: additional storage is provided by the bedrock fractures (Gleeson et al., 2014; Jasechko et al., 2016; Martin et al., 2021), possibly caused by rock stress and high erosion rates and by the bedrock geology, which has influence on groundwater retention capacity (Hayashi, 2020). Second, the area covered by Quaternary deposits could be an insufficient proxy of the groundwater storage potential: the knowledge of the thickness of these deposits (i.e., their volume) and the bedrock topography are crucial factors for controlling groundwater storage (Arnoux et al., 2021; Hayashi, 2020), but corresponding data are not available to date.

Fyw* values of the hybrid catchments reveal a weak positive correlation with Quaternary deposits (ρSpearman=0.13, p value = 0.74), while for rainfall-dominated catchments they show a negative correlation (ρSpearman=-0.52, p value = 0.2); however, both correlations are not statistically significant. These weak correlations suggest that Fqd represents only a limited part of the catchment geology responsible for groundwater flow and that it can only be considered as a first-order measure of geological groundwater storage.

We furthermore observe that Fqd decreases with mean catchment elevation in our data set (Fig. 7b), revealing a negative statistically significant correlation (ρSpearman=-0.5, p value < 0.01). This negative correlation reflects the fact that Fqd decreases when the mean slope increases (Arnoux et al., 2021).

To conclude, we stress that more catchments and more geological information would be required to statistically validate these observations about the role of the groundwater storage potential for explaining young water fraction variations.

The values of LFD for all the study sites are reported in Table 2. Specifically, LFD is lower for hybrid catchments (median of LFD = 0.39), and it is increasingly higher for rainfall (median of LFD = 0.50) and snow-dominated catchments (median of LFD = 0.62). In hybrid catchments, the presence of rain and snowmelt events spanning large parts of the year and the relatively low evapotranspiration (compared to rainfall-dominated catchments) due to reduced temperatures (Goulden et al., 2012) dramatically reduces the duration of low-flow periods, and this is also visible from the recurring discharge peaks (Fig. 8). In low-lying, rain-dominated catchments, evapotranspiration and precipitation are respectively higher and lower than in hybrid catchments, leading to longer low-flow periods (usually during summer and autumn). Under current climate and according to our data set, in snow-dominated catchments, we observe longer winter low-flow periods (streamflow decreasing below 0.5 to 1 mm d-1 for the highest locations; see Fig. S7) on an annual scale than in hybrid catchments. To gain additional insights into the high LFD in snow-dominated catchments and the low LFD in hybrid catchments, it is necessary to further consider the role of snowpack persistence, discussed in the following section. The variations of LFD with elevation are shown in Fig. 11b.

Low-flow periods are typically baseflow dominated (or old water dominated). Accordingly, as anticipated in Sect. 4.3, the variation of Fbf between catchments reflects the proportion of the low-flow duration during the PoS. We observe that the higher the LFD is, the higher the Fbf is: in fact, they are strongly positively correlated (ρSpearman=0.97, p value < 0.001) as shown in Fig. 10. The negative correlation between LFD and Fyw* is lower (ρSpearman=-0.74, p value < 0.001; Fig. 11a) but nevertheless suggests that LFD is an important predictor for Fyw*.

We explore next the presence of an ephemeral or seasonal snowpack as a relevant factor for the time concentration of liquid water input and for LFD. We consider the FSCA, calculated as reported in Sect. 3.2, as a proxy of the snowpack persistence. The FSCA values for all the study sites are reported in Table 2. The underlying fSCA time series for six representative study catchments (two for each hydroclimatic regime) are reported in Fig. 12 (for complete results, see Fig. S4). All the catchments characterized by a seasonal snow cover (i.e., snow dominated) reveal a high FSCA (>0.40, median of FSCA=0.51). Gradually smaller FSCA values correspond to increasingly more ephemeral snowpacks with intermittent snowmelt events during the winter season (Petersky and Harpold, 2018), as reflected by the spiky fSCA time series of hybrid and rainfall-dominated catchments (Fig. 12).

Our results exhibit a bell-shaped behavior of Fyw* with varying FSCA (Fig. 13a). Specifically, we observe a general increase of Fyw* for FSCA values roughly below 0.3. This result can be explained considering that especially in hybrid catchments (median of FSCA=0.28), but partially also in rain-dominated catchments (median of FSCA=0.13), streamflow receives relatively more young water from ephemeral snowpacks. These short-lived snowpacks melt during the winter season resulting in only a short delay between precipitation input and melt (i.e., no water aging in the snowpack), and correspondingly meltwater flows off quickly into the stream (reducing LFD, Fig. 14), e.g., in presence of a frozen surface soil layer. In fact, ephemeral and slightly thick snowpacks do not protect the underlying soil from freezing (Harrison et al., 2021; Rey et al., 2021). Even for low-elevation locations (<≈1500 m a.s.l.), freezing conditions are regularly observed during winter (Keller et al., 2017).

For FSCA values roughly higher than 0.3, we observe a decrease of Fyw* with FSCA; here all the catchments of our data set are snow dominated. The mechanisms at play here are as follows: (i) in catchments with seasonal snowpacks, streamflow receives snowmelt in spring and summer that is at least partly older than 2–3 months (because part of the snow fell more than 3 months before the melt occurs); and (ii) the building up of a persistent, deep snowpack can promote deep vertical infiltration during the main melt period, either by insulating the soil and thereby preventing/reducing freezing (Harrison et al., 2021; Rey et al., 2021; Jasechko et al., 2016) or by gradual soil thawing during the melt period (Rey et al., 2021; Scherler et al., 2010). The temporal dynamic of snow accumulation and melt supports the pivotal role of snowmelt in recharging groundwater during summer in high-elevation environments (Cochand et al., 2019; Du et al., 2019; Flerchinger et al., 1992). A similar result was also found for dolomitic catchments (such as BCC and OVA) by Lucianetti et al. (2020), who discovered that different proportions of rain and snow contribute to the recharge of springs in the Dolomites, with a gradually higher meltwater contribution in springs with increasing elevation. This role of snowmelt supports our analytical choice of computing Fyw* through the “direct input” approach, thus considering the snowpack as part of the catchment storage. In addition, the potentially large shares of meltwater that recharge groundwater via deep vertical infiltration also result in old water sustaining winter baseflow (Fig. S5): the persistent snowpack and the absence of a liquid water input favor a groundwater storage release that creates a longer winter low-flow period that increases LFD (Fig. 14), thus reducing Fyw*, as discussed in Sect. 4.4.

FSCA is strongly correlated with the mean catchment elevation in our data set (ρSpearman=0.97, p value < 0.01; Fig. 13b). A posteriori, we could have considered mean elevation instead of FSCA as a proxy for snowpack persistence. However, a priori, it could be approximative to describe the snow cover persistence only with the increasing elevation: the persistence of snow in a catchment also depends on overall topographic and climatic characteristics, specifically relating to snow and aspect (Painter et al., 2023). In fact, catchments with very different characteristics (e.g., different elevation ranges and different areas) can reveal a similar mean elevation, but the snowpack persistence could considerably change. This is the reason why we focused on FSCA that integrates these physical factors.

The above mechanisms are unable to explain the hydrological function of the glacier-dominated NBPV catchment, which has a very high Fyw* and is an outlier among the snow-dominated catchments (Fig. 13a). The high Fyw* of the high-elevation glacier-covered (42 %) catchment can be explained considering that the glacier melt produces high amounts of streamflow that transit the glacier system very quickly during the summer, given generally fast englacial and subglacial flow paths and the often limited water storage capacity in the glacier forefield (Müller et al., 2022; Saberi et al., 2019; Jansson et al., 2003). Schmieder et al. (2019) also found a high young water fraction in an Austrian glacier-covered (35 %) catchment, leading them to the conclusion that the basin behaves locally like a “Teflon basin” with quickly transmitted ice melt.

The identified key drivers of young water fractions for rainfall-dominated, hybrid and snow-dominated catchments can conveniently be summarized into a perceptual model of the involved hydrological processes and their seasonal interplay (Fig. 15).

High-elevation catchments are characterized by long winter low-flow periods, resulting from the build-up of a seasonal snowpack, and are sustained by the emptying of groundwater (or old water) storage. Accordingly, such storage releases stored water, mainly old meltwater, for prolonged periods where the snowpack can last for several months (typically from December to early April) before releasing water during the melting season. Such seasonal snowpack can protect the underlying soils from freezing, thus promoting meltwater infiltration and groundwater recharge. From this viewpoint, snowpack is considered as part of the catchment storage, and there is a thin line between groundwater and meltwater in snow-dominated catchments. Snowmelt or rain events push out old meltwater to the stream during summer, suggested by the relatively high amount of daily baseflow during the melting season. During this period, the high catchment wetness might even lead to saturation and thereby favor fast flow paths of meltwater or rainwater, which in turn can temporarily increase the young water fraction. Despite this increase during high-flow periods, the prevailing winter low-flow periods in such systems lead to a reduction of the average annual young water fraction.

In catchments with an ephemeral snowpack, at lower elevations, snowmelt events occur regularly during winter such that water released from the corresponding short-lived snowpack is likely younger than 3 months. Moreover, ephemeral snowpacks do not protect the underlying soils from freezing, and rapid flow paths can emerge during episodic or long-term soil surface freezing, by increasing the young water fraction. The high Fyw* of such systems is also explained by the simultaneity of snowmelt and rain events during extended parts of the year (leading to large volume of annual precipitation) and the relatively low (compared to rainfall-dominated catchments) evapotranspiration. Both processes increase the catchment's wetness and reduce the low-flow period's length.

Finally, at the lowest elevations, lower amounts of precipitation and higher evapotranspiration favor longer low-flow periods, mainly sustained by old groundwater from alluvial aquifers, which lead to both a Fyw* and a catchment wetness reduction. Further, the relatively flat topographies at the lowest elevations favor slow flow paths increasing the transit times of water.

How well current hydrological models can represent the interplay of these processes along elevation gradients is left for future research, but our perceptual model builds a solid basis for an improvement of theory-driven models (Clark et al., 2016).