3.1 Atmospheric data

The ERA5 reanalysis dataset is the highest temporally and spatially resolved global reanalysis dataset to date (Hersbach and others, Reference Hersbach2020). Variables at surface and pressure levels are available in hourly time steps at a horizontal resolution of approximately 31 km. Surface variables of temperature, relative humidity, pressure, wind velocity and cloud cover are used to generate the climatic forcing for the coupled snowpack and ice surface energy and mass balance model in python (COSIPY). Therefore, ERA5 data is extracted at the four closest grid cells to the AWS and statistically downscaled to the local conditions at the AWS by quantile mapping (Gudmundsson and others, Reference Gudmundsson, Bremnes, Haugen and Engen-Skaugen2012). Quantile mapping is a technique for downscaling climate-model data via statistical bias correction by adjusting the cumulative distribution function of the model data to the observed data. It has been successfully applied in recent studies in Southern Patagonia (e.g., Weidemann and others, Reference Weidemann2018, Reference Weidemann2020) and shows a good performance in the Monte Sarmiento Massif (for evaluation results, see supplementary table S1 in Temme and others (Reference Temme2023)). Since wind velocities at the AWS are strongly influenced by the local topography, we decided to take this variable directly from the ERA5 data. Statistically downscaled air temperature and pressure are spatially interpolated from the AWS over the topography using a linear temperature lapse rate and the barometric equation, respectively. By fine-tuning the parameters within both the atmospheric and melt model, we determined a lapse rate of $0.60 \, {\rm K}\,(100\, {\rm m})^{-1}$ (Temme and others, Reference Temme2023). This estimate is consistent with values previously used in the region (e.g., Strelin and Iturraspe, Reference Strelin and Iturraspe2007; Koppes and others, Reference Koppes, Hallet and Anderson2009) and the average obtained from the ERA5 dataset. The generated high-resolution dataset of atmospheric conditions at the study site is used to force COSIPY following the approach in Weidemann and others (Reference Weidemann2020) and for the climatological analysis of extreme events. The precipitation is downscaled by an orographic precipitation model (see the following section). The required input is taken from ERA5 and consists of upwind information on geopotential height, air temperature, wind vectors and relative humidity between 850 hPa and 500 hPa and total precipitation over the study site. We use the horizontal integrated water vapor transport (IVT) to detect atmospheric rivers.

3.2 Orographic precipitation model

Since precipitation events can be highly variable spatially and temporally, downscaling is challenging over complex terrain. Furthermore, observations in southern Patagonia are known to be error-prone due to strong winds (Schneider and others, Reference Schneider2003, Reference Schneider, Kilian and Glaser2007). Thus, linear extrapolation of such sparse and uncertain observations with an elevation-dependent lapse rate is critical. Therefore, precipitation is simulated following a physically motivated approach using a linear model of orographic precipitation (Smith and Barstad, Reference Smith and Barstad2004; Barstad and Smith, Reference Barstad and Smith2005; Sauter, Reference Sauter2020), which has been shown in previous studies to reproduce in-situ measurements and their temporal variability well over mountainous terrain (e.g., Schuler and others, Reference Schuler2008; Jarosch and others, Reference Jarosch, Anslow and Clarke2012; Weidemann and others, Reference Weidemann, Sauter, Schneider and Schneider2013, Reference Weidemann2018; Sauter, Reference Sauter2020; Temme and others, Reference Temme2023). The model is based on the linear steady-state theory of orographic precipitation and calculates the precipitation resulting from forced orographic uplift over a mountain, assuming saturated and stable conditions. The cloud water and hydrometeor density are given from advection, condensation due to terrain-forced uplift, and the conversion of cloud water to hydrometeors, as well as the fallout of those producing precipitation (Smith and Barstad, Reference Smith and Barstad2004; Barstad and Smith, Reference Barstad and Smith2005; Sauter, Reference Sauter2020; Weidemann and others, Reference Weidemann2020). The total precipitation is calculated by adding the orographic precipitation computed by the model to the large-scale precipitation, which is given by removing the orographic component from the ERA5 precipitation (Weidemann and others, Reference Weidemann, Sauter, Schneider and Schneider2013, Reference Weidemann2018; Sauter, Reference Sauter2020; Weidemann and others, Reference Weidemann2020; Temme and others, Reference Temme2023). The model parameters include a threshold of relative humidity above which precipitation can occur (90%), determined on observations, and the fallout and conversion time of hydrometeors ($1200 \, {\rm s}$), calibrated for the Monte Sarmiento Massif, in combination with surface-mass balance model parameters based on observations of geodetic mass balance (Temme and others, Reference Temme2023).

3.3 Glacier mass balance and runoff model

Similar to Weidemann and others (Reference Weidemann2020), we use an updated version of the COSIPY model (Sauter and others, Reference Sauter, Arndt and Schneider2020) to estimate the glacier's total runoff. The runoff, including meltwater and liquid precipitation, represents the liquid water flux leaving the glacier system (Cogley, Reference Cogley2010). The model performance of COSIPY was compared to three different surface mass balance models of varying complexity in the Monte Sarmiento Massif (Temme and others, Reference Temme2023). Mass balance estimates of COSIPY agree well with the other model results and show good performance with regional and local geodetic mass balance estimates and ablation stake measurements (Temme and others, Reference Temme2023). COSIPY combines a surface energy balance with a multi-layer subsurface snow and ice model, where the computed surface meltwater serves as an input for the subsurface model (Sauter and others, Reference Sauter, Arndt and Schneider2020). The total ablation includes surface melting, which is calculated by solving all energy fluxes at the glacier surface, sublimation and subsurface melting. Accumulation is possible through snowfall, refreezing and deposition. Snowfall is derived from downscaled precipitation, distinguishing between solid/liquid phases with a logistic transfer function scaling around a threshold temperature of 1.0 °C. Furthermore, the model was extended with a basic parameterization of snowdrift (Warscher and others, Reference Warscher2013; Temme and others, Reference Temme2023), modifying the snowfall distribution based on the topography and the prevalent wind direction. The simulations cover the Monte Sarmiento Massif, including Schiaparelli Glacier, with a 200 m spatial and three-hourly temporal resolution for 2000–2022. The model parameters were partly calibrated (albedo of ice and firn and ice roughness length) and partly fixed based on sensitivity tests and reference values. For a detailed description of the model setup, calibration and evaluation, we refer to Temme and others (Reference Temme2023) and Tables 1 and S2 therein.

3.4 Discharge model

Pressure readings from the water-level sensor are converted to relative water levels of Lago Azul by the hydrostatic equation, accounting for the ambient air pressure. The relative water level of 0 m corresponds to the lowest point of the lake outflow at Rio Azul, when no discharge would be possible. The discharge was measured at the outlet of Rio Azul over a cross-section of $\approx 20 \, {\rm m}$ (Fig. 2). Following the velocity area method, water flow velocity measurements were taken at 1 m intervals (Morgenschweis, Reference Morgenschweis2018). A two-point method was used, measuring the flow velocity at 20% and 80% of the water depth in 2018 and 2019 and a fixed depth approach in 2022. A total of 14 discharge measurements were conducted at different lake levels to establish a relationship between discharge and lake level (Fig. 3). The discharge-lake-level relation follows a power function of the form f(x) = ax ⁿ (Morgenschweis, Reference Morgenschweis2018). We achieve the best fit with a coefficient of determination R ² = 0.87 using the coefficient a = 0.51 and the exponent n = 0.32. We use the 95% prediction interval to provide model uncertainties.

Figure 3. Empirical discharge function (blue line) representing the relationship between lake level and discharge.

3.5 Identifying extreme meteorological events

Environmental responses to intense and frequent climate and weather extremes are complex and globally diverse (Karl and others, Reference Karl, Nicholls and Gregory1997). To quantify extremes, the Expert Team on Climate Change Detection and Indices (ETCCDI) suggests a set of 27 temperature and precipitation indices to assess terrestrial climate variability and change (Karl and others, Reference Karl, Nicholls and Ghazi1999; Peterson and others, Reference Peterson2001, Reference Peterson2002). Six consecutive days of daily maximum temperatures in the upper and lower 10th percentile of maximum temperature centered on a five-day window (1961–1990) are defined as a warm spell duration index (WSDI) or cold spell duration index (CSDI), respectively (Karl and others, Reference Karl, Nicholls and Ghazi1999; Peterson and others, Reference Peterson2001; Zhang and others, Reference Zhang, Hegerl, Zwiers and Kenyon2005). In southern South Patagonia, hardly any events (eleven warm spells and five cold spells) of six consecutive days could be attributed to WSDI or CSDI from 2015 to 2022. Thus, four instead of six consecutive days, as defined above, are used to identify warm or cold spells in accordance with the 90th percentile of all identified consecutive days. We used a base period from 1991 to 2020 as suggested by the World Meteorological Organization (WMO). Additionally, we count the number of consecutive wet days (CWD) (consecutive dry days (CDD)) of at least (less than) 1 mm daily precipitation sum. Wet and dry spells are identified if the number of consecutive days exceeds the 90th percentile of all identified CWD and CDD (i.e., 17 and 7 consecutive days, respectively).

3.6 Atmospheric river tracking

We detect and track landfalling atmospheric rivers (ARs) with an Image-Processing-based Atmospheric River Tracking method (IPART) (Xu and others, Reference Xu, Ma, Chang and Wang2020b). While conventional detection methods of ARs typically use either IVT thresholds (e.g., ${\rm IVT} \geq 250 \, \hbox{kg m}^{-1} {\rm s}^{-1}$) or a relative IVT magnitude threshold (e.g., 85th percentile of local climatology) (Ralph and others, Reference Ralph, Neiman and Wick2004; Dettinger and others, Reference Dettinger, Ralph, Das, Neiman and Cayan2011; Lavers and others, Reference Lavers, Villarini, Allan, Wood and Wade2012; Rutz and others, Reference Rutz, Steenburgh and Ralph2014), the IPART algorithm works by the ‘top hat by reconstruction’ technique (Xu and others, Reference Xu, Ma, Chang and Wang2020b). Additionally, this method can capture even the genesis and decaying stage of single ARs, especially in high-latitudes where less water vapor is present in the atmosphere (Xu and others, Reference Xu, Ma, Chang and Wang2020a,Reference Xu, Ma, Chang and Wang2020b).

According to Xu and others (Reference Xu, Ma, Chang and Wang2020b), we set a geometrical filter to drop ARs with an area smaller than 5×10⁵ km² or greater than 18×10⁶ km², a length subceeding 800 km or exceeding 11 000 km and having a length-width-ratio of smaller than two. We evaluate all ARs with their centroids inside $120 ^\circ$W and $60 ^\circ$W and $10 ^\circ$S and $80 ^\circ$S. Due to the high spatial resolution of the ERA5 dataset, the kernel size (E) has been adapted to E = [16, 18, 18] (number of grid cells). We assume that any precipitation event in the study area that falls within the contours of a detected AR of at least one reanalysis time step per day is associated with an AR (Viale and others, Reference Viale, Valenzuela, Garreaud and Ralph2018).

3.7 Lake sounding

In April 2018, bathymetric measurements of Lago Azul were conducted using a Garmin Echomap Plus 42cv echosounder mounted on a touring kayak. At three-second intervals, lake depth measurements were taken along parallel transects spaced 40 m to 60 m apart (Fig. 4). Subsequently, the resulting 14 100 lake depth measurements were interpolated to the entire lake area by the Triangulated Irregular Network method (Peucker and others, Reference Peucker, Fowler, Little and Mark1976).

Figure 4. Bathymetric map of Lago Azul. The red line represents the survey grid of April 2018. The black lines show the glacier retreat, which has been derived from UAV mosaics captured in October 2016, March 2017, March 2018, April 2019, March 2020 and January 2022.

3.8 Photogrammetric processing

Two identical monoscopic camera systems (Canon EOS 1200D, as shown in Fig. 5) recorded changes in the glacier-front position and on the glacier surface (Fig. 2). The lower camera system (example image in Fig. 6) was installed close to the glacier terminus and operated from October 2015 until March 2019 (Weidemann, Reference Weidemann2021). The upper camera system has been operating since March 2018, and it is located approximately 200 m above the glacier terminus perpendicular to the main glacier flow (example image in Fig. 5). Based on a time interval of two hours, images with similar illumination and lighting were chosen on a three-to-five-day frequency. To estimate the ice-flow velocity from the selected camera images, we use the Python-based open-source tool PyTrx (How and others, Reference How, Hulton, Buie and Benn2020). The tool is adaptable, performing image transformations of 2D images into a real-world coordinate system and feature tracking for ice-flow velocity estimates. PyTrx uses a pinhole camera model that assigns each pixel of the image coordinate system (u,v) into a world coordinate system (X _w, Y _w, Z _w),

(1)$$z_c \left(\matrix{u\cr v\cr 1 }\right) = P \left[\matrix{X_w\cr Y_w\cr Z_w\cr 1 }\right],\; $$

Figure 5. The digital single-lens reflex camera (DSLR) system and time-lapse images. (a) Installed time-lapse camera system. (b) Original image from the upper time-lapse camera on November, 23 2020. The dashed black frame refers to the zoomed-in section captured in the images shown in (c) to (f). The dotted frame refers to the zoomed-in section captured in (g) and (h). This sequence of images presents the largest calving events on record. (c) Ice front image from November 19, 2020 and its fracture line (dashed red line) and (d) from November 20, 2020 immediately after the calving event. (e) Ice front image from November 1, 2021 and its fracture line (dashed red line), and (f) from November 3, 2021 after the calving event. (g) Ice front image from April 27, 2021 and (h) from April 29, 2021 after the calving event.

Figure 6. Relative position of the glacier front and rate of length change were derived from the lower (blue dots) and upper (red dots) time-lapse camera. The corresponding line indicates the centered 30 d rolling mean. The thick black line shows the water level relative to the reference height. The rate of length change is depicted in the panel above as centered 30 d rolling mean in m d⁻¹. The images above show the ice front from the lower camera system in November 2016 (left) and January 2022 (right). The background color indicates the ERA5 daily temperature anomaly with respect to the 2015–2022 mean. The 75% of the longest-lasting identified wet, and dry (top), cold, and warm spells (bottom) are shown separately in the upper panel. The roman letters within the Figure correspond to the following assignment: I – both camera systems were operated simultaneously; II – largest observed calving event in November 2020 (cf. Figs. 5c, d); III – calving event in April 2021 (cf. Figs. 5g, h); IV – calving event in November 2021 (cf. Figs. 5e, f).

where z _c is an arbitrary scaling factor and P the camera perspective projection matrix (Xu and Zhang, Reference Xu and Zhang1996). P comprises internal camera properties denoted as the intrinsic camera matrix K and the external camera matrix such as orientation and location,

(2)$$P = {\bf K} [ {\bf R}\vec{T}] ,\; $$

with the rotation matrix R and the translation vector $\vec {T}$ (Xu and Zhang, Reference Xu and Zhang1996). The pinhole camera model does not consider distortion effects due to the camera lens (Xu and Zhang, Reference Xu and Zhang1996). PyTrx does evaluate the radial and tangential distortion coefficients and the intrinsic camera matrix using a technique based on the OpenCV toolbox by using black-white chessboard camera images (How and others, Reference How, Hulton, Buie and Benn2020). The extrinsic camera matrix is determined by the exact location and camera pose (How and others, Reference How, Hulton, Buie and Benn2020). Therefore, the camera position must be measured by the differential global positioning system (DGPS), and the pose must be estimated using a stereo reference camera technique. For the latter, we used the photogrammetric processing software AgiSoft PhotoScan Professional (Version 1.7.0) (2020). We estimated the camera pose based on camera images from 17 different DGPS-measured locations and common features in the image plane with the corresponding DGPS-measured position markers, so-called ground control points (GCP). Appropriate GCP are stable features in the camera field view of known world coordinates, such as boulders, quartz veins in rocks, or mountain peaks.

Because very small variations (${\cal O} \approx 10^{-4\, \circ }$) of the estimated pose lead to large deviations (${\cal O} \approx 10 {\rm m}$) in the transformation (Equation (1)), PyTrx has included a camera pose optimization routine based on GCP to refine the estimated camera model (How and others, Reference How, Hulton, Buie and Benn2020). Combined with a digital elevation model (DEM) retrieved from multiple UAV surveys during subsequent field campaigns in 2016, 2017, 2018, 2019, 2020 and 2022, a world coordinate is assigned to each pixel of the image coordinate system.

3.9 Ice-flow velocity estimates

PyTrx uses the sparse feature-tracking approach that produces a spatially more detailed velocity map than the alternative dense feature-tracking method. Sparse feature tracking identifies patterns in the image plane with unique pixel-intensity distributions between image pairs (How and others, Reference How, Hulton, Buie and Benn2020). Static features visible in the fore- and background of the image plane correct the camera motion. When the feature-tracking or motion correction fails, it produces unrealistic movement patterns that are too high or against the main direction of the ice flow. Thus, we filtered for derived velocities within the 95 % confidence interval and for the direction of movement with orientation along the main flow of the glacier. As the final estimated ice-flow velocity derived from one image pair, we use the mean of all estimated ice-flow velocities that fall inside a circle ($r_{\rm P1} = 400 \, {\rm m}$) close to the terminus (Fig. 2).

However, the camera images only produce a detailed temporal estimate of the ice flow near the terminus. Ice-flow velocity estimates from SAR obtained from the Sentinel-1 mission provide a spatial view of the ice flow over the entire glacier. SAR data is independent of daylight, cloud cover, weather and the sun's illumination of Earth's surface and thus appropriate to study the ice flow in heavily cloudy regions such as southern South Patagonia (Jawak and other, Reference Jawak, Bidawe and Luis2015). Worldwide post-processed Sentinel-1 velocity maps of 12 glacierized regions outside the large polar ice sheets are available on the online application RETREAT (2021) (Friedl and others, Reference Friedl, Seehaus and Braun2021). RETREAT presents an open-access interactive web interface providing spatial velocity maps with a spatial resolution of 200 m and a time interval of 6–48 days since 2014 (Friedl and others, Reference Friedl, Seehaus and Braun2021). We calculated the ice-flow variation along the centerline in 50 m intervals. Here, we consider the mean ice flow within a circle of 400 m (Fig. 2).

3.10 Glacier terminus changes and calving flux

The terminus line T is defined as the dividing line between the glacier front and lake water. We determine the terminus line in the image plane and project it into the world coordinate system using PyTrx. Projecting a terminus retreat on a DEM causes errors in assigning the respective world coordinate whenever the terminus line is projected on the glacier front or surface. Thus, we use a modified DEM instead, where the glacier height is equal to the lake surface. The resulting terminus line on the lake surface is separated into 1 m intervals. For each interval i, we calculate the distance δT _i to the newly estimated terminus position parallel to the centerline (Fig. 7). By considering their means ($\overline {\delta T}$), we retrieve a time-dependent terminus length change relative to the initial terminus position.

Figure 7. Schematic representation of the calculation of glacier length changes. $T_{t_0}$ is the initial terminus position and $T_{t_0 + \Delta t}$ the position at any time step Δt. Length changes are calculated parallel to the centerline (dashed line) in 1 m increments.

To evaluate the reliability of the estimates of glacier-length change of both camera systems, we calculated changes along the ice front using a sample image pair from both the lower and the upper camera system. This process was repeated 20 times, with the position of the ice front determined manually each time, resulting in a standard error of 0.06 m d⁻¹ and 0.08 m d⁻¹ for the lower and upper camera estimates within the camera coordinate system, respectively. In addition, we georeferenced the camera model projections onto the DEM to align with the terminus line determined by the UAV missions (Fig. 4) to reduce the offset to the real world coordinate system.

We estimate the calving flux using a combined approach of a fixed flux gate located upstream of the calving front position and the temporal glacier terminus position (Evans and others, Reference Evans, Fraser, Cook, Coleman and Joughin2022). Let $T_{t_0}$ be the ice-front position at the time t ₀ and $T_{t_0 + \Delta t}$ the new observed ice-front position after any time step Δt. Without any calving, the ice-front position would be pushed forward by the glacier motion and reach a new simulated position,

(3)$$T_{{\rm sim}, t_0 + \Delta t} = T_{t_0} + v_{\Delta t} \cdot \Delta t ,\; $$

where we assume the ice-flow velocity (v _Δt) is the observed mean velocity close to the terminus occurring during Δt (Fig. 8). The calving flux (q _c) is calculated by the difference between the simulated and observed ice-front position,

(4)$$q_{c, t_0 + \Delta t} = ( T_{{\rm sim}, t_0 + \Delta t} - T_{t_0 + \Delta t}) \cdot w \cdot h \cdot \rho_{\rm ice},\; $$

with the width w of the ice-front. The ice thickness h is estimated by the sum of the bathymetry measurements of the lake depth close to the terminus (Fig. 2) and yearly DEMs based on the UAV missions. Intra-annual changes are assumed to be linear. By considering the density of ice $\rho _{ice} = 900 \, {\rm kg.m}^{-3}$, we calculate the water equivalent calving flux (Equation (4)). This approach neglects subaqueous melting and assumes that any change along the ice front is spread across the entire ice depth.

Figure 8. Schematic illustration of calving flux calculation between two terminus positions T at two time steps, t = t ₀ (black line) and t = t ₀ + Δt (grey line). The simulated terminus position is shown in green. Similar to the estimation of glacier length changes (Fig. 7), changes parallel to the centerline (dashed line) are calculated in 1 m increments.

3.11 Time-series analysis

Separation of the spatial and temporal signatures of glacier velocity allows us to identify the primary driving force acting on ice-dynamical processes in response to atmospheric forcing. In many cases, several temporal signals overlap, with seasonal fluctuations often superimposed on low-frequency signals. To separate the signal in its short- and long-term contribution, we emulate the original signal by linear combinations of elementary functions. Riel and others (Reference Riel, Minchew and Joughin2021) suggest splitting the signal into a short-term seasonal contribution by third-order B-spline functions, which may vary in amplitude from year to year. Long-term changes, including non-steady and non-periodic signals, are represented by time-integrated B-spline functions (Riel and others, Reference Riel, Minchew and Joughin2021). This methodology is especially suited for discontinuous and heterogeneous time series. Its performance was tested on Greenland's surface ice-flow velocity estimates based on Sentinel-1 data (Riel and others, Reference Riel, Minchew and Joughin2021).

To investigate calving's response (a non-linear dataset) to an extreme event (non-linear phenomena), we first apply a peak detection method (Du and others, Reference Du, Kibbe and Lin2006). The peak detection identifies local maxima of the original data set, in our case the calving flux. If there is a peak in calving flux within five days after an extreme weather event, the event is considered a potential cause. We test the resulting frequency's significance by comparing this result to surrogate datasets. Surrogates are used to generate pseudo-observations that approximate the calving flux by having the same power spectrum and amplitude distribution. We generated 10 000 surrogates by an iterative amplitude adjusted Fourier transform (IAAFT) algorithm (Kantz and Schreiber, Reference Kantz and Schreiber2004; Venema and others, Reference Venema, Ament and Simmer2006). When the original dataset's peak contribution of events such as landfalling AR or the onset of warm, cold, wet and dry spells is greater than the 95th percentile of the surrogate samples, the results are considered statistically significant.

We use a Spearman rank-order test to assess the statistical dependence between the rankings of two variables. Throughout the study, we only mention significant correlations (i.e., p ≤ 0.05).