Statistical models for climate variability

There is no agreed definition of ‘variability’ for a particular climate variable. Here a framework which aims at decomposing the temporal fluctuations of a given meteorological time series into three components, called the year-to-year, month-to-month and day-to-day variability, is proposed. The decomposition permits these components to be acted on individually when using a weather generator to derive synthetic time series. The series are then used to force a mass-balance and ice-dynamics model, thus revealing the effect on the glacier evolution. The general idea is to consider deviations from a detrended long-term mean, describe these deviations with an appropriate statistical model, and parameterize the residuals of that model in order to obtain a suitable metric for variability. Detrending of the time series is necessary since ‘naively analyzing time series which have a trend leads to a trend-induced inflation of variability’ (Reference Scherrer, Appenzeller, Liniger and SchärScherrer and others, 2005). Here a statistical model is defined as ‘appropriate’ if the residuals ε of that model have the properties of white Gaussian noise, i.e. are independent and identically distributed (i.i.d.) following a normal distribution with zero mean and scale parameter σ (i.e. i.i.d.). The scale parameter σ is then the desired ‘suitable metric for variability’.

For the sake of simplicity, and considering the information readily available in future projections, the analyses are constrained to the two variables temperature and precipitation. In the measured meteorological time series, the correlation between these two variables is weak at any time aggregation (Fig. 3). If any, a weak anticorrelation (coefficient of determination ~0.11) can be found for yearly values (very dry years tend to be warm; very wet years tend to be cold). This allows the two variables to be considered separately in the first instance, although some dependency will be introduced.

Temperature variability

Detrending of the temperature time series is performed with a STL decomposition (i.e. Seasonal Trend decomposition procedure based on Loess; see Reference Cleveland, Cleveland, McRae and TerpenningCleveland and others, 1990). The time series detrended in this way is then aggregated to yearly values T _yr. Analysis of the autocorrelation function (ACF) and the partial autocorrelation function (PACF) of this new time series reveals that an autoregressive moving-average (ARMA) model (Reference WhittleWhittle, 1951; Reference Box, Jenkins and ReinselBox and others, 2008) of order p = 1 and q = 1 is appropriate for describing it. In general, an ARMA(p, q) model describes the evolution of a given random variable X as

(1)

where X_t is the value at time t, c is a constant (c = 0 throughout this study), a_i and b_j are coefficients to be estimated and i.i.d. is a noise term with value ε_t at time t (the residual). The coefficients a_i and b_j are estimated according to the algorithm by Reference Gardner, Harvey and PhillipsGardner and others (1980) as implemented in the software package R, and the values are listed in Table 2. For convenience, the ‘ARMA(1,1) model fitted to the time series of annual anomalies of the detrended time series’ will be referred to as the model. The scale parameter σ of the residuals of this model is estimated with (where sd(ε) denotes the standard deviation of ε) and is chosen to define the year-to-year variability. In the following, this parameter is denoted by (Table 2).

Table 2. Coefficients (coeff) and standard errors (s.e.) as estimated for the different ARMA models from the analysis of the observed meteorological time series during the reference period 1980–2009

The mean monthly temperature for month i (T _{mon, i} ) can be described in terms of a deviation ΔT _mon, _i from the mean annual temperature T _yr (i.e.T _{mon, i} = T _yr +ΔT _mon, _i ). This deviation can be further decomposed into a month-specific mean deviation which characterizes the mean deviation of month i from T _yr (e.g. on average, the mean temperature for January will be some degree lower than the annual mean, whereas, on average, August will have a mean temperature higher than the annual mean), and an additional deviation characterizing the deviation of the particular month from (e.g. the mean temperature of a particular January may well differ from the temperature expected considering the mean annual temperature for the given year and the average deviation of the month January from it). This concept, which is visualized in Figure 2a, can be formalized as

(2)

Fig. 2. Conceptual representation for the decomposition of the detrended (a) temperature and (b) precipitation time series. In each plot, a randomly selected time series of 1 year’s length is shown. Note that for precipitation, daily values are shown in the inset of the bottom right only. The individual symbols are explained in the text.

Fig. 3. Coefficient of determination for the dependency between temperature and precipitation in the observed (red) and simulated (black) time series during the reference period 1980–2009. For the simulated time series, the median (solid line) and the 95% confidence interval (dotted) are shown. Aggregations are performed as sum (precipitation) or mean (temperature) of daily values.

For the definition of month-to-month variability, a model for is required. Analysis of the ACF and PACF indicates that an ARMA(3,1) model is suitable for describing this term. The coefficients of this model, called the model, are estimated in the same way as for . Similarly, the scale parameter of the model residuals, , is the desired metric for the month-to-month variability (Table 2).

Exactly the same approach is used to define the day-to-day variability. In analogy to Eqn (2), one can write

(3)

Again, the concept is visualized in Figure 2a. For , inspection of the ACF and PACF indicates an ARMA(2,4) model. This model is called the model, and the scale parameter of the residuals, , is the metric for the day-to-day variability.

With the aim of mimicking some dependency between temperature and precipitation, the residuals of the model are analyzed separately for wet and dry days. The observation that the distributions differ in the two cases (not shown) is included by estimating two separate coefficients and for wet and dry days respectively (Table 2). This will be taken into account when generating synthetic time series. Note that by introducing the dependency at the daily timescale, the dependency is also propagated to any aggregated data.

Precipitation variability

Because precipitation cannot be negative, the framework as described for temperature cannot be applied in exactly the same way. However, the general idea is maintained. Since the annual precipitation sum P _yr can be regarded as strictly positive (years without precipitation can be virtually excluded in the considered climate setting), a log-transformation is suitable for deskewing the distribution (Reference Mosteller and TukeyMosteller and Tukey (1977) call this a ‘first-aid transformation’). After removal of the mean value, analyses of the ACF and PACF reveal that no particular model is required for having a signal with the characteristics of white Gaussian noise, and one can write i.i.d. The parameter for the year-to-year variability is then , and is estimated with (Table 2).

For the monthly values, a decomposition similar to that for temperature is applied, whereby the deviations are considered from the monthly sum which would arise if the yearly precipitation P _yr were uniformly distributed over the 365 days of the year. In analogy to Eqn (2) one can write

(4)

Here P _mon, _i is the precipitation sum for month i, n _days, _i the number of days in that month, the month-specific average deviation from the monthly sum given by the uniformly distributed precipitation, and the additional deviation for the particular month (Fig. 2b). Fitting a model directly to is not suitable, since the distribution of the quantity is slightly skewed (negative deviations are constrained by the fact that P _mon, _i ≥ 0). This problem is handled by adding the absolute value of the maximal possible negative deviation (in order to obtain positive values) and log-transforming the corrected values (for deskewing the distribution). The variable transformed in this way can be described with an ARMA(1,1) model (the model), and the scale parameter of the residuals, , is the metric describing the month-to-month variability. The coefficients estimated for the model are listed in Table 2.

Since precipitation is a positive quantity, the idea pursued so far is no longer suitable for describing daily values, and the approach is adapted. In particular, the two models set up for P _yr and P _mon are not required for the analysis of daily precipitation, but are used later when generating synthetic time series. The idea (first presented by Reference RichardsonRichardson (1981) and often used) is to describe the daily precipitation time series with a combination of a two-state first-order Markov chain (e.g. Reference DeilyDeily, 1966) for the succession of wet and dry days, and a Γ-distribution for the precipitation sums in wet days. ‘Two-state first-order Markov chain’ means that the model (hereafter referred to as the Markov chain model, MCM) describes a process with only two possible states (wet or dry); the state for a particular time-step is only dependent on the state of the time-step before (‘first-order’), and the transition between states can be described through distinct probabilities (the idea of a ‘Markov chain’). Defining a state variable Z_t which assumes the values Z_t = 0 for a dry day and Z_t = 1 for a wet day, the (conditional) probabilities that need to be defined are (1) P00 = P{Z_t = 0 |Z_{t −1} = 0} (probability of having two consecutive dry days), and (2) P11 = P{Z_t = 1|Z_{t −1} = 1} (probability of having two consecutive wet days). The complementary probabilities are then given by P01 = P{Z_t = 1|Z_{t −1} = 0} = 1 – P00, and P10 = P{Z_t = 0 |Z_{t −1} = 1} = 1 – P11, and this fully describes the model. For the Γ-distribution, two parameters κ. and θ, describing the shape and scale respectively, need to be estimated. This is done with and where is the daily precipitation amounts for wet days. For the definition of day-to-day variability, P00 and P11 rather than κ. and θ are used, which seems the more reasonable choice since altering one of the two probability parameters necessarily influences the distribution of the daily precipitation amount as well. This is because when generating synthetic time series, the monthly precipitation sum will be given a priori by the model. The values estimated for the individual parameters are listed in Table 2.

Generation of daily weather data

The decompositions described above can be used in an inverse way to generate synthetic time series. In order to preserve the (weak) dependency between temperature and precipitation, precipitation time series are generated first. This is done in four steps: First, a time series with the desired length is generated for the yearly precipitation totals by taking a random sample from the distribution , and back-transforming the values (yearly sums were centered and log-transformed before). In a second step, a series of monthly anomalies of the given length is generated with the model. After back-transformation, these anomalies are superimposed on a year-by-year basis onto the monthly sum which is given by distributing the yearly precipitation uniformly over the days of the year. In rare cases where the superposition leads to negative values, the difference is uniformly distributed over the remaining month of the year (e.g. if for the October of a given year the superposition leads to a monthly precipitation sum of −11 mm, the precipitation sum for October will be set to 0 mm and the sum of all other months in that year decreased by 1 mm). This procedure guarantees consistency with the previously generated yearly totals in all cases. In a third step, a daily sequence of wet and dry days is generated with the MCM model, and in the fourth, final step, a daily precipitation sum is assigned to each day defined as wet. This happens by sampling a series of values from the fitted Γ-distribution. Consistency between daily totals and monthly sums is enforced by scaling the daily values with an appropriate factor.

Once a precipitation time series has been created, the associated temperature time series is generated according to the following scheme: First, a time series of yearly temperature anomalies is generated with the model. Second, the same is done for the monthly anomalies by using the model. In a third step, two time series are generated for the daily anomalies with the model. In the first time series, the variability parameter is set to , and in the second to . Consistency between the two time series is guaranteed by setting the random seed of the two generating processes to the same value. In a fourth step, the different anomalies are superimposed on the corresponding long-term means, giving a synthetic, detrended time series in daily resolution. When superimposing the daily anomalies, the value is chosen from one or the other time series according to the wet/dry condition given from the previously constructed precipitation time series. Finally, a trend is added to the time series in order to shift the mean value to the desired level (following the previous steps only would give time series with a long-term mean of 0°C). Note that within this framework, ensembles of time series generated with different sets of variability parameters have exactly the same mean values on a yearly, monthly and (for temperature) even daily basis.

Validation of the weather generator

The weather generator is validated by generating a sample of 100 time series for the reference period 1980–2009 and comparing a set of characteristics to the values derived from the observed time series. The set of characteristics includes: (1) For temperature: average and standard deviation (SD) of daily temperatures in the course of the year (365 comparisons for each time series, one per day of the year); average and SD of monthly temperatures in the course of the year (12 comparisons for each time series, one per month of the year); average and SD of annual temperatures (1 comparison per time series); average and SD of positive degree-days (PDDs) per year (i.e. yearly sum of temperatures >0°C); average warm-spell length (i.e. number of consecutive days with temperatures >0°C); and average cold-spell length (i.e. average number of consecutive days with temperatures ≤−5°C). (2) For precipitation: number of wet days per year; average and SD of precipitation amount for wet days; average and SD of monthly precipitation sums in the course of the year (12 comparisons per time series); average and SD of annual precipitation sum (1 comparison per time series); average and SD of the yearly precipitation occurring at a temperature <1.5°C (as proxy for accumulation); average wet-spell length (i.e. average number of consecutive days with precipitation); and average dry-spell length (i.e. average number of consecutive days without precipitation).

Following Reference Kou, Ge, Wang and ZhangKou and others (2007) and Reference MinMin and others (2011), the performance of the weather generator is assessed by evaluating the number of individual, synthetically generated time series for which a significant difference occurs in a particular characteristic. The significance of the differences for mean and variances is assessed with the tests by Reference WilcoxonWilcoxon (1945) and Reference Levene, Olkin, Ghurye, Hoeffding, Madow and MannLevene (1960), respectively. Spell lengths, PDDs and precipitation characteristics are log-transformed prior to testing for reducing the skewness. Differences are ascertained to be significant according to the P-value yielded by the test statistic, and the results grouped in four different classes of significance (Table 3) following Reference Kou, Ge, Wang and ZhangKou and others (2007).

Table 3. Validation of the weather generator. For each characteristic, the percentage of realizations generated for the reference period 1980–2009, and falling within a given difference level, is listed. Differences are classified to be very significant (VSD) for P < 0.01, moderately significant (MSD) for 0.01 ≤ P < 0:05, slightly significant (SSD) for 0:05 ≤ P < 0.10 and not significant (NSD) for P ≥ 0.1 (P being the P-value of the test statistic). The mean of the characteristic for the observed and synthetically generated time series is given by ‘obs.’ and ‘gen.’, respectively. Abbreviations: avg = average, sd = standard deviation, SL = spell length, WDY = number of wet days per year, PBT = yearly precipitation occurring at temperatures below the snow/rain threshold (i.e. 1.5°C). Temperature and precipitation statistics are given in 8C and mm, respectively, SL in days

The validation shows that the weather generator is capable of satisfactorily (i.e. ≥90% of the time series showing non-significant differences (NSDs) at the 10% level) mimicking the observed time series in most of the considered characteristics, and in the characteristics which are expected to have a major influence on the glacier response (e.g. the PDD statistics and the proxy characteristics for accumulation) in particular. Slight tendencies can, however, be observed in (1) underestimating the SD of daily temperatures if considered in the course of the year on a day-by-day basis (only 85.5% of NSDs), (2) underestimating the length of warm and cold spells (86% and 88% of NSDs, respectively), (3) underestimating the number of wet days per year (89% of NSDs), (4) overestimating the SD of the precipitation amount for wet days (78% of NSDs), (5) underestimating the SD of monthly precipitation sums if considered on a month-bymonth basis (87.1% of NSDs) and (6) underestimating the length of wet spells (87% of NSDs, which is a consequence of (3)).

One may argue that these tendencies can be regarded as acceptable for the presented application since (1) the differences occurring for the SD of daily temperature and precipitation are mainly contained in the 5–10% level of confidence, and (2) the role of precipitation will be shown to be negligible when compared to temperature, which relativizes the importance of the precipitation characteristics.

The degree to which the dependency between temperature and precipitation is preserved in the synthetically generated time series is assessed by computing the coefficient of determination (e.g. Reference Box, Jenkins and ReinselBox and others, 2008) between the two variables for aggregation lengths ranging from 1 to 365 days. Aggregation is performed by computing mean and total values for temperature and precipitation respectively. The obtained values are then compared to those calculated from the observed time series. Figure 3 shows that the characteristic of the dependency is well maintained. At most, the synthetic time series show a slight tendency to underestimate the dependency for long periods of aggregation.

Variability scenarios

For all models included in the weather generator, reference values for the variability parameters (i.e. , , P00 and P ₁₁, with i = [day, month, year]) are determined by analyzing the measured meteorological time series (last row in Table 4; red lines in Fig. 4). Scenarios for an altered climatic variability are then constructed in two different ways: In a first set of scenarios, the reference values are systematically doubled or halved (scenarios with ending ‘d’ in Table 4), and in a second set, the parameters are adjusted in order to explore the range of variability expected in the future according to the results of the ENSEMBLES model chains (scenarios with ending ‘E’ in Table 4). For the second set, the relative changes with respect to the reference period 1980– 2009 are computed for a given parameter and a given GCM/ RCM model chain in a running window of 30 year width (Fig. 4). The scenarios are then constructed in order to explore 95% of the range of these changes (bars on the right-hand side of Figure 4a–c and e–g).

Table 4. Summary of the scenarios (‘Scen.’) defined for temperature and precipitation variability. The σ-parameters are given as factors relative to the reference value determined from observed meteorological time series (‘Obs.’) while for the P-parameters the stated coefficients are additive. ‘Same as observed’ means that the time series of the variable was not generated with the given model but obtained by shifting the observed time series as described in the text

Fig. 4. Temporal evolution of the defined variability parameters (a–c, e–g), and long-term temperature and precipitation trends (d, h) according to six GCM/RCM model chains. Model chains with noticeable trajectories are labeled (see Table 1 for numbering). (a–c), (e) and (f) show relative deviations during a given 30 year interval from the values calculated for the reference period (1980–2009). In (d), (g) and (h) deviations are given as absolute values. The red curve depicts the values derived from the measured meteorological data. The bar on the right-hand side of (a–c) and (e–g) shows the range containing 95% of the data. In (d) and (h) the thick black line is a 30 year running median of the ensemble.

When generating the scenarios, three cases are distinguished depending on how the temperature and precipitation time series are obtained. In the first case, temperature is generated for the period 2010–2100 (91 years) with the corresponding models, while the time series for precipitation is constructed by adopting the observed records for the period 1920–2010 (also 91 years), adjusted with the long-term trend given by the GCM/RCM model chains (a more detailed explanation follows shortly). In the following, this set of scenarios will be referred to as the ‘temperature-only scenarios’ since the variability in precipitation is left unchanged. In the second case, the observed temperature for the period 1920–2010 is corrected with the long-term trend given by the GCM/RCM model chains, whereas the precipitation time series is generated with the given models. This set will be referred to as the ‘precipitation-only scenarios’ since the temperature variability is unaltered. In the third case, both temperature and precipitation are generated synthetically, and the set is referred to as the ‘combined scenarios’.

The temperature-only scenarios include nine different combinations in which the individual variability parameters are varied systematically: scenario T.ref is the reference scenario in which all parameters concerning the temperature time series are kept at the same level as estimated from the observed meteorological time series, scenarios T01–T06 are constructed by varying one variability parameter at a time, and in scenarios T07 and T08 all parameters are varied together. The 11 precipitation-only scenarios are constructed in a similar way. P.ref is the reference scenario, P01–P08 are scenarios in which the variability parameters for precipitation are varied one by one, and P09 and P10 are scenarios in which all parameters are varied together. The combined scenarios include scenario TP1, in which all variability parameters of both temperature and precipitation are increased, and scenario TP2, in which all variability parameters are decreased. The values for the individual variability parameters used in the different scenarios are reported in Table 4. Note that a particular case is given by the parameters steering the day-to-day variability of precipitation, since they express a probability. In this case, the range in which the parameters are varied in the scenarios is not defined through the relative deviation from the reference period, but by the spread of the parameter values in the six model chains. The spread is computed, and then centered around the parameter value estimated from the observed meteorological time series.

Since all scenarios are meant to represent possible future conditions, long-term trends are added to both the temperature and precipitation time series. The trends are defined to be the median of the deviations from the reference period computed for the six model chains over a running window of 30 years (black line in Fig. 4d and h). Linearly extrapolated to the period 2085–2114 and compared to the reference period 1980–2009, the trends result in an increase of +4.2°C in mean temperature, and a decrease of 51 mm in mean annual precipitation. These trends are added to all the constructed scenarios on a year-to-year basis, meaning that the time series of a particular year is generated first, and the value corrected a posteriori with the according trend. For temperature, the correction is additive (e.g. for the year 2100, 4.2°C are added to the generated time series), whereas for precipitation the correction is multiplicative (e.g. for the year 2100, the generated time series is multiplied by (2260 – 51)/2260b = 0.97, since the annual precipitation in the reference period was 2260 mm). For each of the named scenarios, a set of 100 synthetic time series spanning the time period 2010–2100 is generated, and used to force the combined glacier mass-balance and ice-dynamics model described hereafter.

Modeling of glacier evolution

The evolution of Rhonegletscher is simulated using the generated meteorological time series to force the ice-dynamics model presented by Reference Jouvet, Picasso, Rappaz and BlatterJouvet and others (2008). The latter works in combination with a mass-balance model based on the approach by Reference HockHock (1999). This model combination has been used before to successfully reconstruct and project the transient evolution of both Rhonegletscher (Reference Jouvet, Huss, Blatter, Picasso and RappazJouvet and others, 2009) and Grosser Aletschgletscher, Swiss Alps (Reference Jouvet, Picasso, Rappaz, Huss and FunkJouvet and others, 2011b), during the periods 1874–2100 and 1880–2100, respectively.

As described in Reference Jouvet, Huss, Blatter, Picasso and RappazJouvet and others (2009), the ice-dynamics model treats the glacier ice as an incompressible non-Newtonian fluid and neglects inertial terms. Thus, the mass and momentum equations reduce to a stationary nonlinear Stokes problem in the ice domain Ω:

(5)

where ε(u) = (∇u + ∇u ^T )/2 is the rate of strain rank 2 tensor, ρ = 900 kg m⁻³ is the ice density and g = (0, 0, 9.81) m s⁻² is the vector of gravitational acceleration. Ice viscosity μ is a function of the velocity field u = (u, v, w), as described by Glen’s flow law (Reference GlenGlen, 1955):

(6)

in which n = 3 is the flow law exponent, A is the flow rate factor and bar is a regularization parameter which prevents infinite viscosity for zero strain. Boundary conditions for Eqn (5) are given at the glacier surface and base. At the surface, no forces apply:

(7)

(n is the unit outer normal vector along the boundary of the ice domain Ω, and p is pressure), whereas at the base the sliding condition reads:

(8)

In Eqn (8), t ₁ and t ₂ are two orthogonal vectors tangent to the ice–bedrock interface, and α a sliding coefficient given by

(9)

where C is a positive value to be tuned, and s ₀ = 0:01 m a⁻¹ is a regularization parameter which prevents infinite α for zero velocity.

Glacier evolution is then calculated by solving the transport equation

(10)

where φ = φ(x, y, z, t) is the characteristic function (φ = 1 if location (x, y, z) ∊ Ω at time t, and φ = 0 otherwise), and bρ is a source term describing the change of glacier mass due to accumulation and ablation (b is mass balance).

For any location (x, y, z), daily mass balance b is computed by subtracting daily surface ablation c, calculated as

(11)

(Reference HockHock, 1999), from daily surface accumulation a, calculated as

(12)

(Reference Huss, Bauder, Funk and HockHuss and others, 2008; Reference Farinotti, Usselmann, Huss, Bauder and FunkFarinotti and others, 2012), i.e. b = a − c. Contributions of internal and basal mass balance are neglected. In Eqn (11), f _M is a melt factor,r _snow/ice are two distinct radiation factors for snow and ice, I _{pot, (x, y, z} ) is the potential direct clear-sky solar radiation at location (x, y, z) and is the mean daily air temperature at the same location. For days with , no ablation occurs. The spatial distribution of is obtained by interpolating the temperature synthetically generated for the reference location using a constant lapse rate. In Eqn (12), P _ref is the precipitation given by the synthetically generated time series (which refers to the center of the glacier, as a reference point ‘ref’), C _prec is a correction factor accounting for the gauge-catch deficit (Bruce and Clark,1966), z – z _ref is the elevation difference between the reference and the considered location, dP/dz is the lapse rate with which precipitation increases with elevation (Reference Peck and BrownPeck and Brown, 1962), D _{snow, (x, y)} is a spatially distributed factor which accounts for snow redistribution processes (e.g. Reference Tarboton, Chowdhury and JacksonTarboton and others, 1995; Reference Huss, Bauder and FunkHuss and others, 2009) and r _s is the fraction of solid precipitation. D _{snow, (x, y)} is determined from characteristics of the surface topography (Reference Huss, Bauder, Funk and HockHuss and others, 2008), while r _s decreases linearly from 1 to 0 in the temperature range T _thr − 1°C to T _thr + 1°C, where T _thr = 1.5°C is a threshold temperature distinguishing snow from rainfall (Reference HockHock, 1999).

Numerical solutions to the equations concerning the ice-dynamics model are found by decoupling the computation of φ from that of u and p through a time discretization, and using two different space discretizations to solve the transport problem (Eqn (10)) and the nonlinear Stokes problem (Eqn (5)). The transport problem is solved using a structured grid of small cubic cells (with the goal of minimizing numerical diffusion), whereas the nonlinear Stokes problem is solved on an unstructured mesh of tetrahedrons with larger size (since the task is computationally expensive). Further details on the numerical implementation of the model are provided by Reference Jouvet, Picasso, Rappaz and BlatterJouvet and others (2008).

For Rhonegletscher, both the parameters of the ice-dynamics model and the parameters of the mass-balance model have been calibrated before by Reference Jouvet, Huss, Blatter, Picasso and RappazJouvet and others (2009) and Reference Farinotti, Usselmann, Huss, Bauder and FunkFarinotti and others (2012), respectively. For the present study, these values are adopted without modification (Table 5). Details of the calibration procedures, which include comparison to measured surface velocity fields, surface mass balance, ice volume changes and runoff, are provided in the aforementioned publications.

Table 5. Parameters (‘Param’) for the ice-dynamics and mass-balance model calibrated for Rhonegletscher (Reference Jouvet, Huss, Blatter, Picasso and RappazJouvet and others, 2009; Reference Farinotti, Usselmann, Huss, Bauder and FunkFarinotti and others, 2012). The column ‘Eqn’ indicates the equation in which the parameter appears