Aerial photographs: extent losses

Two aerial surveys were used in the present study:

1. 1. The Pirineos-Sur flight (September 1981; scale ∼1: 25 000; black and white)

2. 2. The Gobierno de Aragón flight (September 1999; scale ∼1 : 20 000; colour).

The glacial perimeters observed in the 1999 flight were updated using field data from the 2005 glaciological campaign (GPS measurements of glacial perimeters and visual analysis of oblique aerial photographs of the ice bodies). The GPS measurements were made at the end of the ablation season, using a GeoExplorer CE XT (Trimble) receiver. A semi-kinematic positioning procedure was used, recording data at intervals along the glacial perimeters. The raw data collected in the field were later post-processed using Pathfinder Office software (v. 2.9) to obtain sub-metre horizontal accuracy.

The mapping of glacial perimeters in the aerial survey of 1981 was carried out after the images were geometrically corrected and georeferenced (the 1999 flight was already orthorectified, as it was used to generate the DEM scale 1 :5000 distributed by the Aragonese Government) (Fig. 3). These two processes were carried out using the Georeferencing module of ArcGIS, using as reference for control points the orthophotos and elevation data from 1999. The obtained horizontal root-mean-square error (RMSE) of the set of control points for the different photograms ranged between 2.5 and 5.0 m, and was considered precise enough for our purposes. A cubic convolution resample procedure (recommended for continuous data) was applied to generate the final rectified images. The georeferenced glacial perimeters (1981, 2005) extracted from the images and the GPS mapping (in conjunction with DEM data) were used to calculate surface losses, changes in maximum, minimum and mean altitudinal glacial location, and volumetric losses.

Fig. 3. (a) Three-dimensional view of Maladeta glacier after superimposing the geometrically corrected and georeferenced aerial photograph of the 1981 Pirineos-Sur flight in the 1981 DEM (glacier perimeter is indicated with a black curve). (b) Oblique aerial photograph of the present-day (2005) Maladeta oriental and occidental glaciers; the major volumetric losses registered in the small tongue of Maladeta oriental glacier are evident.

DEMs: volume losses

The use of DEMs from different dates is already well implanted in glacial studies as a source to estimate changes in ice volume and analyze mass balance (Reference Favey, Wehr, Geiger and KahleFavey and others, 2002), and it has been applied in several mountainous regions of the world (e.g. Alaska (Reference Arendt, Echelmeyer, Harrison, Lingle and ValentineArendt and others, 2002; Reference Cox and MarchCox and March, 2004), the Andes (Reference Jordan and UngerechtsJordan and others, 2005; Reference Mark and SeltzerMark and Seltzer, 2005; Reference Rivera, Bown and CasassaRivera and others, 2005a), Patagonia (Reference Rignot and RiveraRignot and others, 2003; Reference Rivera and CasassaRivera and Casassa, 2004; Reference Raymond, Neumann, Rignot, Echelmeyer and RiveraRaymond and others, 2005; Reference Rivera, Casassa and BamberRivera and others, 2005b) and the European Alps (Reference Kaufmann and LiebKaufmann and Lieb, 2002)).

The procedure is based in the comparison, in a GIS context, of different DEMs. In our case, two elevation models were used:

1. 1. DEM 1981. This DEM was obtained by digitizing contour lines (10 m interval) from 1 : 25 000 cartography edited by the Spanish Instituto Geográfico Nacional (Mapa Topográfico Nacional de España; sheets 180-I, Benasque and 180-II, Pico de Aneto). These maps were published in 1991 and their cartographic restitution is based in a photogrammetric flight carried out in 1981. Thirty control points were used (homogeneously distributed through the DEM), and their associated RMSE was calculated (±2.3 m) to evaluate the vertical accuracy of the constructed DEM (Fig. 3).

2. 2. DEM 1999. The digital elevation files commercialized by the Cartographic Service of the Gobierno de Aragón were used. With 1 : 5000 scale and 1 m contour interval, this DEM is based in the photogrammetric restitution of the 1999 aerial survey already mentioned (Gobierno de Aragón flight). Its estimated RMSE for vertical accuracy is ±1.5 m.

The combined vertical RMSE of both DEMs (±2.74 m) was considered precise enough for our purposes (the ice-depth losses obtained were generally much higher than this value).

After the preparation of the models, the final estimation of ice depth and total volume losses was performed in ArcGIS comparing for each glacier surface, by cut-and-fill procedures, the differences of altitudinal values observed between the 1981 and 1999 DEMs.

Climatic data: temperature and precipitation

In areas where no systematic glacial mass-balance studies have been carried out, the application of temperature and precipitation series to understand melting and accumulation processes is useful. In our case, precipitation and temperature data from, respectively, 45 and 16 weather stations corresponding to the national net of the Spanish Instituto Nacional de Meteorología were used. The period studied was 1950–2002. Owing to the lack of stations located in the glaciated areas, all available registers located in the upper sections of the Cinca, Ésera, Noguera Ribagorzana and Noguera Pallaresa valleys were used to obtain a representative regional series (Fig. 4). All datasets were at least 20 years long into the period 1970–2002. The missing monthly data were filled by applying linear regression, using as independent variables the stations best correlated with the dataset to be filled.

Fig. 4. Location of the weather stations used to obtain the regional series.

The precipitation and temperature series were converted into regional indexes that summarized the variation of the variables in the whole area during the period 1950–2002 on a monthly and a seasonal basis. These indexes can be defined as the normalized average of the normalized variables and were developed in three steps (Borradaile, 2003).

1. 1. The original monthly and annual series were normalized in standard deviation units relative to the average over a reference period (1970–2002).

2. 2. The average of each variable was calculated. The possibility that a sector might have a major influence on the average as a consequence of a higher density of observations was avoided by weighting each weather station by its influence area, quantified in this case by means of Thiessen’s polygons (Reference Jones and HulmeJones and Hulme, 1996).

3. 3. The averaged time series was normalized.

This procedure requires that temperature and precipitation series fit to a Gaussian distribution. The goodness-fit test of Kolmogorov–Smirnov was used to check this assumption. In most of the cases, temperature series showed a Gaussian distribution. However, several precipitation series did not show normality until they were converted with a logarithmic transformation.

The temporal trends in climatic series (1950–2002) were analyzed by a rank correlation method, using Spearman’s ρ, a non-parametric test that, in this context, provides information about the relation between the climatic series and time. This statistic is favoured because it is neither sensitive to the presence of outliers nor to the existence of non-linear correlations (Borradaile, 2003).

Solar radiation

The relationship between solar radiation and glacier evolution (development, recession) has been analyzed in several works during the last decade (Reference Hastenrath and GreischarHastenrath and Greischar, 1997; Reference Hock, Johansson and JanssonHock and others, 2002; Reference Chueca, Julián and RenéChueca and Julián, 2004; Reference Mark and SeltzerMark and Seltzer, 2005) due to its impact on the ablation rate. Here, the total potential incoming shortwave solar radiation in the study area is calculated with the module INSOLDIA of the MiraMon GIS (Reference PonsPons, 1998). For each cell of the reference DEM, the potential solar radiation (measured in 10 kJ m^–2 d^–1 µm^–1) was estimated for both the summer months (July–September) and the annual period, as both time spans are interesting in terms of glacial mass balance (Fig. 5a and b). In the process, the program accounts for site latitude, altitude, orientation, shadows cast by surrounding topography (azimuth precision: 10°; elevation precision: 1°), daily shifts in solar angle (measured hourly) and solar incidence angle for each cell, Earth–Sun distance (monthly) and the effect of atmospheric attenuation (as there are no nearby weather stations, standard values were adopted for atmospheric transmittivity and diffuse proportion of solar radiation). The ground albedo factor is not included in the model (Reference PonsPons, 1998).

Fig. 5. Summer (a) and annual (b) potential solar radiation In the study area (glacier perimeters In 1981 and 2005 are Indicated).

Climatic evolution

Table 1 shows the trends in temperature and precipitation over the period 1950–2002. Noticeable differences in the sign and significance (α < 0.05) of the tendencies of each parameter through the year can be observed. Minimum temperatures show a significant decrease during April, May and June, whereas the maximum temperatures increase significantly in March, June, July and August; for mean temperature, only the increase registered in August presents statistical significance. Precipitation shows significant decrease in February, March and June.

Table 1. Trends in temperature and precipitation: correlation coefficients (Spearman’s ρ) between temperature/precipitation and time (1950–2002) in the study area (significant correlations at the 95% level are indicated with asterisk)

The evolution of temperature and precipitation during the periods of the year that better represent the glacial mass balance was analyzed to assess the relation between climatic trends and glacier retreat, specifically:

1. The precipitation accumulated during the months in which this variable is registered as snow and freeze processes take place, and

2. The average temperature of the months during which melting processes are dominant.

The determination of these periods was based on the calculation of the altitude of the 0°C mean monthly isotherm, obtained by analyzing the thermal gradient in the study area (relating the average temperature of each month, from the period 1970–2002, with the elevation of the weather stations used in the work; Table 2).

Table 2. Correlation coefficient, R, between altitude and mean temperature and thermal gradients in the study area

The altitude at which different isotherms are located throughout the year is indicated in Figure 6. An increase of gradient during the warm months is observed, which tends to diminish progressively during the coldest months. The glaciers of the Maladeta massif are all located (nowadays and at the beginning of the 1980s) above 2700ma.s.l. The period in which the accumulation of snow dominates extends from November to May, while melting takes place from June to October. October is included in the period of ablation, although its 0°C isotherm is at ∼2650 ma.s.l., because of the minimal altitudinal difference from the glacial termini and the reduced contribution during this month to the annual snowfall registered in the study area.

Fig. 6. Altitude of isotherms throughout the year (Q°C isotherm is indicated with thicker curve).

Figure 7 shows the evolution of the minimum, maximum and mean temperatures during the ablation period, and the precipitation during the accumulation period for the interval 1950–2002. Minimum temperature values display a cyclic pattern throughout the past few decades. From 1950 to 1970, positive values predominate, while the 1970s are characterized by the persistence of negative anomalies. In the 1980s, positive values again predominate, but those of negative sign dominate again from the 1990s to the end of the studied period. The persistence and intensity of the negative values during recent years explains why the tendency line shows globally a small descent, although this is lacking in statistical significance (ρ = −0.21; α > 0.05; Fig. 7a). The evolution of the maximum temperature values differs from that described for the minimum values. Although the values present cycles with an approximate duration of 10 years, they maintain a persistent positive tendency from the middle of the 1950s until today (statistically significant; ρ = 0.50; α < 0.05). During the stage 1981–2002, only four years registered values below the average of the reference period, and on eight occasions the positive anomalies exceeded one standard deviation (Fig. 7b). Mean temperature values show an intermediate behaviour with regard to the series already mentioned. A positive and significant tendency is obtained, although with a markedly lower slope than that observed for the maximum values (ρ = 0.34; α < 0.05) (Fig. 7c). The evolution of the precipitation during the accumulation period presents two well-differentiated phases (Fig. 7d): (1) 1950–80, when positive anomalies or near to average values are observed; and (2) 1980–2002, in which negative anomalies clearly dominate, particularly from the end of the 1980s until the mid-1990s. During this most recent period (in which the glacier evolution studied here is framed), on only five occasions was the average of the 1950–2002 stage surpassed. Globally, the calculated general tendency presents a statistically significant negative coefficient (ρ = −0.35; α < 0.05).

Fig. 7. Evolution of temperatures (during the ablation period) and precipitation (during the accumulation period): 1950–2002 (data for the 1980–2002 period are shown with a black curve).

Surface and volume losses

The magnitude of glacier recession in the study area is shown in Tables 3 and 4 and in Figure 8. All glacial bodies present a similar evolution, with evident extent and volumetric losses and increases in the mean altitude of each glacier.

Table 3. Extent and volumetric losses in the Maladeta glaciers (the percentage of surface loss in Maladeta glacier was calculated after adding the 2005 extent of its two present-day fragments: Maladeta occidental and Maladeta oriental glaciers)

Table 4. Maximum, minimum and mean altitude (m a.s.l.) of the Maladeta glaciers (the 2005 data for Maladeta Glacier were obtained averaging the altitudes of its two present-day fragments: Maladeta occidental and oriental glaciers)

Fig. 8. Extent losses (glacier perimeters In 1981 and 2005 are Indicated) and ice-depth losses (for the 1981–99 period) observed in the Maladeta glaciers.

During the period 1981–2005, the glaciers of the Maladeta massif receded 35.7% in surface area, from 240.9 to 155.0 ha. The surface-loss rate was 3.57 ha a^–1. Ice-volume losses between 1981 and 1999 amounted to an estimated total of 0.0137 km³, an annual rate of 0.763 10⁶ m³ a^–1 (as data on the glacial volume in 1981 were not available, it was not possible to assess the relative magnitude of these losses from the initial mass of each glacier). Given an average ice density of 0.9 g cm^–3, the total ice thickness lost in the Maladeta massif was 75.6 m w.e (4.2 m w.e. a^–1). Data from glaciers with different extent were compared using the ratio of volume loss to initial surface (VL/IS) registered during the period 1981–99 (with the initial surface that each glacier had in 1981). The VL/SL index value for the massif as a whole over the period 1981–99 was 5.70 (0.31 VL/IS units a^–1). Finally, the mean altitude of the studied glaciers increased between 1981 and 2005 by a total of 43.5 m (1.81 m a^–1), from 3026.9 to 3070.4 m a.s.l. This parameter, calculated from the average of the altitudinal value of all pixels classified as glacial surface, was chosen for its adequacy to evaluate glacier regression in small cirque glaciers such as that analyzed here. In such glaciers, which present very irregular morphologies, the usual measure of length reduction along one or several longitudinal axes is less representative than this global value.

The most noticeable differences in the observed shrinkage trends are directly linked to the northern or southern exposure of the studied glaciers and glacierets (Fig. 8). This effect was quantified by grouping the values of extent and volume losses, and the increase in altitude into two sets: north-facing ice masses (northeast aspect in practically all cases; including Alba, Maladeta, Aneto, Barrancs, Tempestades and Salenques occidental glaciers and Salenques oriental glacieret) and south-facing ice masses (southwest aspect in these cases; including Coronas glacier and Llosás, Cregüeña occidental and Cregüeña oriental glacierets).

The major volumetric and extent losses and altitudinal changes have been observed in the south-oriented glaciers and glacierets. During the study period, these glacial bodies decreased in area by 83.9% (from 16.9 to 2.7 ha), had a VL/ IS index of 12.28 (0.68 VL/IS units a⁻¹) and average altitude in the case of Coronas glacier increased 75 m (3.12 ma⁻¹) from 3081 to 3156 m a.s.l. The other south-oriented ice masses experienced a total degradation, and thus their altitudinal migration is not calculable. The north-facing glaciers diminished their surfaces 32.1% (from 224.0 to 152.2 ha), had a VL/IS index of 5.20 (0.28 VL/IS units a⁻¹) and their average altitude increased by 48.2 m (2 m a⁻¹) from 3005 to 3053 m a.s.l. In this exposure, only Salenques occidental glacier and Salenques oriental glacieret showed complete degradation.

A bivariate correlation analysis was performed to measure the strength of the association between some of the variables that control glacial evolution at the detailed scale. The variables studied for each glacier and glacieret were: mean summer and annual solar radiation received on glacial surfaces (1981), VL/IS index, mean initial altitude (1981), initial size (1981), percentage of surface loss (1981–2005) and increase in mean altitude (1981–2005). Summer and annual values of potential solar radiation, calculated for the area corresponding to the 1981 surface of each glacier, are shown in Table 5. Additional variables were obtained from the data listed in Tables 3 and 4. The five cases in which significant associations between variables have been detected (α ≤ 0.05) are those that relate (1) mean summer and annual solar radiation with the VL/IS index, (2) mean summer and annual solar radiation with the increases in the mean altitude (1981–2005) and (3) initial size (1981) with the percentage of surface loss (1981–2005) (Fig. 9; Table 6).

Table 5. Annual and summer potential solar radiation received on 1981 glacial surfaces (in 10 kJ m⁻² d^{− 1} µm^{− 1})

Table 6. Correlation coefficients, R, between selected variables and significance level

Fig. 9. Scatter plots of the relationships between (a) summer solar radiation (10 kJ m⁻² d⁻¹ µm⁻¹) and VL/IS index; (b) annual solar radiation (10 kJ m⁻² d⁻¹ µm^–1) and VL/IS index; (c) summer solar radiation (10 kJ m^–2 d^–1 µm^–1) and increase in mean altitude (m) (1981–2005); (d) annual solar radiation (10 kJ m^–2 d^–1 µm^–1) and increase in mean altitude (1981–2005) (m); and (e) initial (1981) glacier area (ha) and percentage of surface loss (1981–2005). 100% surface loss cases located in the upper left include Salenques oriental, Creguena occidental and oriental and Llosas glaciers). South-oriented glaciers are indicated in italics.