Introduction

Combined heat- and mass-balance studies provide, besides the insight into the transfer processes between atmosphere and ground, a potentially simple tool for indirect evaluation of melt and ablation rates. This implies that the adequacy of the transfer equations as well as the reliability of the collected heat-balance data must be checked against independent direct evaluations of melt and ablation rates, at least during a certain “assessment” period.

During a short summer period of 1970 detailed measuring procedures were determined for short-term snow melt and ablation rates. The study was carried out as a first step in a series of investigations dealing with the mechanisms of mass and energy transfer to and in a snow-pack.

The concrete questions were:

The observations were made at an experimental site, at this time still snow-covered, located in the upper ablation area of Peyto Glacier, Alberta, Canada (lat. 51° 39′ 40″ N., long. 116° 33′ W., elevation 2510 m a.s.l.) during the period 1 to 15 July 1970. The site was chosen in the centre of a nearly level plateau (slope 2°). It was equipped with a net radiometer (for a short description of instruments see the Appendix), a continuously recording meteorological station, an ablatometer, and a gamma transmission probe for continuous snow density profiles. Additional equipment consisted of a pyranograph, a precipitation gauge, evaporation pans, a small snow-melt lysimeter and equipment to measure snow density and liquid-water content of small snow samples.

Theory and Measurements

Mass balance. Limiting the discussion to a melting snow-pack, particularly to a snow column in the uppermost layers of a temperate glacier, the ablation A, for a period with no precipitation, may be expressed by a combined ice and water balance equation as:

where A, the ablation, is the total loss of water in all phases, R is the run-off, E is the water-vapour exchange at the surface, W is the mass exchange by wind action, SM is the snow-melt, and DM is the sub-surface mass change due to storage changes of liquid water. In contrast to the internal mass changes in the pack, the wind action and the vapour exchange at the surface are often negligible quantities for short intervals. The internal mass changes are mainly dependent on the liquid water movement in the pack. For a highly porous, inhomogeneous and unsaturated material like snow, the water movement is controlled, among other things, by the melt intensity. Thus, the snow moisture content changes during the day as the melt intensity does.

Reference HubleyHubley (1954) formulated an expression for the ablation which takes care of these changes and presented all quantities involved as functions of time:

M denotes the total mass of a snow column of height h, z is the vertical co-ordinate, ρ _i the “dry” snow density or the density of the ice matrix and ρ _w is the volume fraction of the total snow density (ρ _s) due to the presence of liquid water. The subscript h indicates the reference location of the terms, in this case a small surface layer. The first two terms on the right in Equation (2) express under the given conditions the melt and compaction in the snow-pack, whereas the next two terms account for the changes in liquid-water storage. This separation of the snow-pack into a solid and a liquid phase (the vapour phase is negligible within the pack under isothermal conditions) and into two zones (surface and sub-surface zone) allows the calculation of melt rates. Heat balance calculations yield melt rates, not ablation rates, therefore measured melt rates are of primary interest whenever a comparison with such calculated quantities is desirable. In addition, melt rates can be evaluated by controlling only the surface layers of a snow-pack, because snow-melt processes are confined to the top 0.3 m of a ripe pack. For the evaluation of ablation rates, the whole snow column extending to an impermeable layer, where the outflow of the water takes place, has to be surveyed. As shown later in this study, the build-up and the fluctuations of a water table on top of an impermeable layer (old ice surface) can significantly influence measured ablation rates.

Assuming that the compaction of the snow-pack can be neglected for short intervals (Reference Ambach and HoinkesAmbach and Hoinkes, 1963, reported for similar conditions a mean value of 2 mm per day), the first two terms of Equation (2) can be integrated. The melt in the interval (t ₁–t ₀) is then given by:

where ρ _iΔh (t ₀) is the initial mean ice density of the surface layer (thickness = Δh) and ρ _iΔh′(t ₀), and ρ _iΔh′(t ₁) are the mean ice densities of the lower layers (thickness = Δh′), which are affected by melt, at the beginning and the end of the interval respectively. The various depth intervals are displayed in Figure 1.

Fig. 1. Snow density profiles at different times, measured with a gamma transmission probe. Values in brackets were obtained gravimetrically as the top layer at the probe location was sometimes influenced by additional melt from the installations.

The ice density values (ρ _i = ρ _s−ρ _w) were calculated by using continuous snow-density profiles (gamma transmission probe) and liquid-water content measurements. The surface lowering Δh was estimated by means of successive surface lowering readings with an ablato-meter. The surface lowering and the density measurements were performed at the same location. There is, however, no technique to measure in situ changes of liquid-water content of snow. Consequently, the liquid water content was obtained by repeated sampling of the layers, using the freezing calorimetric method (Reference Radok, Radok, Stephens and SutherlandRadok and others, 1961).

Δh′ was estimated by using the Bouger–Lambert law:

where I _z is the hourly net short-wave radiation intensity at level z = h ₂, I ₀ is the maximum hourly net short-wave radiation intensity per interval at the minimum surface level z = h ₁. The extinction coefficient, v, was assumed to be 1.8 mm⁻¹ for this wet and ripe snow (Reference MellorMellor, 1964). The net short-wave radiation has been determined by means of the measured short-wave radiation and with mean values of albedo deduced from measurements by Reference MillerMiller (1950). By assigning to I _z a small value of 33.4 kJ m⁻² h⁻¹ which produces the negligible melt of 0.1 mm of water per hour, the maximum melt-layer thickness Δh′ = h ₁−h ₂ can be calculated for each interval:

This thickness varied in a range from 0.14 to 0.22 m during the period of continuous snow cover.

Since it is common practice in combined heat- and mass-balance studies to compare the heat, input with measured ablation rates, the ablation rates were evaluated too. Various techniques reported by Reference LaChapelleLaChapelle (1959) and Reference Müller and KeelerMuller and Keeler (1969) were used to measure these ablation rates. The first one consisted in measuring directly the mass loss of adjacent snow columns in time down to the impermeable, “superimposed-ice” surface.

The ablation A was calculated from

where ρ _s(z, t ₀) and ρ _s(z, t ₁) represent the total snow density profiles at time t ₀ and t ₁ respectively. These successive density profiles were obtained with the aid of the gamma transmission probe. Unfortunately the method could not be applied to the whole observation period, because the installations caused additional melt and influenced the measurements appreciably toward the end of the period.

The second method which could not be performed at the same location but was feasible for the whole period was to sample snow or ice cores with respect to a stable reference horizon according to:

where ρ _s is the average snow density of the cores.

The third method was based on measurement of the surface lowering for each interval and on the initially measured average density.

All melt and ablation rates were evaluated daily for two successive periods with supposedly similar melt amounts. A six-hour afternoon period (12.00 h to 18.00 h) and an eighteen-hour night/morning period (18.00 h to 12.00 h) fulfilled this condition satisfactorily and permitted measurements at convenient times.

To obtain an additional independent measurement for the ablation rate of the snow-pack, at least for a part of the period, a provisional snow-melt lysimeter was installed at the site (Fig. 2). For this purpose a snow block of 0.5 m² surface area was separated by vertical trenches from the remaining pack. At the lower boundary and along the smooth “super-imposed-ice” surface, an additional thin snow layer was gradually removed from three sides for about two-thirds of the area. Before the remaining part of this layer was removed, a large transparent plastic sheet was positioned at this lower, now accessible boundary. By pushing the snow block forward towards the spread sheet the whole block was brought to the centre of the sheet. The side parts of the sheet were then taken up along the walls. The enclosed block was brought back into its original position in the snow-pack, so that only one small corner, where the outlet was installed, was not surrounded by the snow-pack. At day-time the melt-water outflow from this block was collected over intervals of to 2 h in a large container and the volume measured with a graduated cylinder. During the night the small outflow was similarly collected and measured the following morning. Although no continuously recording system could be established for this trial and therefore no continuous outflow curve could be obtained, the total daily outflow could be measured for a few days (cf. values of last column in Table III).

Fig. 2. Provisional snow-melt lysimeter and snow surface conditions.

In order to get another independent check for the heat-balance equations in addition to the residual melt, Q _SM (Equation (9)), direct evaporation measurements were made. The net evaporative loss was determined by weighing three circular, snow-filled plastic pans at the beginning and end of each interval. The pans were about 20 cm deep, had a surface area of 450 cm² and were refilled with surface snow without destroying its surface features and structure. Natural conditions were assured by placing these pans in the snow-pack so that their top rim was flush with the surrounding snow surface. The results of these measurements are represented in the last column of Table 1.

Heat balance. Any heat-balance calculation may be subject to systematic errors, because most of the transfer equations are empirical and the theoretical framework is still not sufficient for the range of atmospheric stabilities experienced. Keeping this and the instrumental limitations of this study in mind, the observation period and the site were selected in such a way that only four quantities had to be considered. The heat available for melting, Q _SM , could be represented by:

where Q _R is the net radiation, Q _H the sensible heat component and Q _E the latent heat component.

A brief outline of the heat balance theory usually applied explains the specific conditions and the necessary assumptions. The net all-wave radiation was measured directly with a net radiometer. The transfer of heat and water vapour was estimated by means of theories, mainly developed by Prandtl and Taylor (cf. Reference BruntBrunt, 1952). According to these the sensible heat flux F _H may be calculated from:

where z is the vertical co-ordinate with its origin at the surface, T the absolute air temperature, Γ the dry adiabatic lapse rate, and C _p the specific heat of air at constant pressure, ρ _a is the density of air and K _H the coefficient of eddy diffusivity. Similarly for the latent heat flux F _E :

where q denotes the specific humidity and K _E the coefficient of eddy diffusion of water vapour. Finally the effect of the turbulent air motion on the transfer process can be described by:

where τ is the mean shear stress, u a mean value of the horizontal component of the eddy velocity and K _M the eddy viscosity of air. It may be noted that the vertical wind component is assumed to be proportional to, and of the same order of magnitude as, u.

The usual procedure is now to evaluate the coefficient K _M using wind profile data and assumptions for the exchange-layer thickness, the stability of the atmosphere and the vertical distribution of the shear stress. However, because of its simplicity, many investigators make use of von Kármán’s logarithmic equation for the wind velocity distribution, even so they dispose, e.g., of detailed wind profile data, which may indicate quite irregular wind profiles. This equation was derived for an adiabatic atmosphere and can be written in the form:

where k is the dimensionless von Kármán constant, τ ₀ the shear stress at the lower atmospheric boundary and z ₀ the surface roughness parameter, a height where the wind velocity is zero. If the shear stress does not change appreciably with the vertical distance z (τ ≈ τ ₀), an assumption which was confirmed by recent investigations of Reference Haugen, Haugen, Kaimal and BradleyHaugen and others (1971), Equations (12) and (13) may be combined and K _M can be calculated from

where u ₁ is the mean horizontal wind velocity at height z ₁. Assuming, additionally, that the eddy diffusivity coefficients are identical for the transfer of momentum, heat and vapour, and assuming that the eddy diffusivity coefficients are constant with height, the different fluxes may be calculated.

Reference Grainger and ListerGrainger and Lister (1966) compared different relations describing the wind distribution over cold surfaces and concluded that a simple logarithmic law is most applicable over a wide range of stability conditions. This conclusion and the limited data available in this study, which covered a period of rather strong inversion (mean air temperature at z ≈ 1.5 m of +7.9° C), led to the application of the outlined logarithmic approach. Mean values of the main meteorological variables for the two daily intervals are shown in Table I and Figure 3.

Fig. 3. Mean values of air temperature, relative humidity, wind speed and cloud amount for a 6 h and an 18 h period for successive 24 h intervals. The totals of net all-wave radiation are also represented for the same daily periods.

The sensible and latent heat gain or loss were calculated for hourly intervals from:

where P _a denotes the atmospheric pressure (taken as constant: 750 mbar), R the universal gas constant, T the mean temperature of the considered air-layer, u ₁ and z ₁ the wind speed and its height of measurement respectively, T ₂ the air temperature and e ₂ the water vapour pressure at the height z ₂, T ₀ and e ₀ the temperature and the vapour pressure respectively at the surface, and L _E the latent heat of condensation. Hourly mean values were used for the calculations. A comparison between temperatures recorded at the Rauchfuss meteorological station and those measured in a wooden Stevenson screen and with an aspirated thermometer suggested that the “Rauchfuss” values were too high during day-time and too low during night-time, probably as a result of intensified radiation influences. Therefore, the air temperatures recorded within the metal screen of the Rauchfuss meteorological station had to be slightly corrected. Because the snow-pack studied was melting throughout the observation period (T ₂ ⩾ + 0.1° C), the snow surface temperature and its vapour pressure were known and assumed equal to T ₀ and e ₀ respectively. During night-time the partial freezing of the liquid water of the surface layer prevented its cooling by outgoing long-wave radiation and/or evaporation. In a first run the surface roughness length z ₀ and the scaling length z ₀′ were assumed to be equal. The surface roughness parameter z ₀ was estimated on the basis of a roughness element description (Reference LettauLettau, 1969):

where h ^* is the effective obstacle height, s the silhouette area measured in the vertical Crosswind-lateral plane and S the specific area of the obstacles in the basal horizontal plane. According to Lettau this approach is especially feasible for periods with light to moderate winds blowing from the same direction. Under such conditions z ₀ is determined by macro-features of the surface rather than by micro-features of the material. Because the average horizontal wind speed was only 2.5 m s⁻¹, the direction mostly down-glacier, and the nearly level surface of the experimental site consisted of fairly regular sun cups during the first 10 d (Fig. 2), the roughness-element description seemed to be adequate. The average silhouette of the cups could be described by a sinusoidal curve with a wave length of 0.4 m and an average amplitude of 40 mm. Consequently h ^* = 80 mm, s = 1.6 × 10⁴ mm², S = 12.6 × 10⁴ mm² and z ₀ = 5 mm.

During the last three days, glacier ice was exposed. In the beginning it consisted of smooth superimposed ice, afterwards of old glacier surface ice. Since the previous procedure was no longer applicable, a surface roughness length z ₀ = 0.5 mm was assumed. This average value was derived from reports of Reference KutzbachKutzbach (1961) and Reference Grainger and ListerGrainger and Lister (1966).

Results and Discussion

The melt rates (SM) were calculated for hourly intervals using the heat-balance equation (9), by

where L _F is the latent heat of fusion. The values obtained were then summed daily over two successive time periods in order to get heat-balance melt rates, which were comparable with the previously mentioned mass-balance melt rates. Table I and Figure 4 show the measured and calculated melt for the first 6 h and the remaining 18 h for every 24 h interval.

Fig. 4. Calculated and measured melt rates for the first 6 h and the remaining 18 h of a 24 h interval.

+ ——— + SM_M, measured melt

○ – – – –○ SM_c1 , calculated melt (Run 1)

● ⋯⋯ ● SM_c2 , calculated melt (Run 2)

As mentioned before, no specific distinction between the z ₀ and a similar scaling length for the temperature and specific humidity profiles was made in the first calculation run. However, because this parameter has a marked effect on the results and various authors suggested that the assumption K _M ≈ K _H ≈ K _E was not valid in a very small sublayer at the surface, a separate scaling length z ₀′ for the temperature and the specific humidity was introduced in a second run. Based on results of Reference SverdrupSverdrup (1936), Reference AmbachAmbach (1963) and Reference HolmgrenHolmgren (1971) z ₀′ was chosen two orders of magnitude smaller than z ₀.

The observation period covers nine days with continuous snow cover (1 to 10 July) and five days with slush or ice-covered ground. During a single period of overcast (11 to 12 July) a total of 11.6 mm of a mixture of rain and wet snow was recorded. Because this precipitation had no substantial heat content and ran off almost as soon as it was deposited on the surface, there was no need to include it in the heat-balance calculations. The previously mentioned measuring procedures could only be fully applied for the period with snow cover, therefore the following discussion is restricted mainly to these conditions. The values of SM _M are measured melt rates, presented as totals for two different consecutive time intervals per day. The values of SM _C1 (Run 1) and SM _C2 (Run 2) are total values too, computed by means of hourly heat-balance calculations. The difference between SM _C1 and SM _C2 indicates the magnitude of deviation which can be expected when different roughness parameters are used in the heat-balance calculations; in the first case (SM _C1 ), only one parameter, z ₀, was used, and in the second case (SM _C2 ), two parameters, z ₀ and z ₀′. Because the second version underestimates the actually measured melt rate almost consistently, preference is given to the first one. The calculated melt rate (SM _C1 ) either over or underestimates the measured melt rate, probably depending on the changing atmospheric stratification, which cannot be taken into account with the heat-balance approach outlined. However, a considerable amount of the deviation can be attributed to measurement errors. The maximum relative error for a single measured melt rate was estimated by partial differentiation of Equation (3):

where Δρ _i ⩽ Δρ _s+Δρ _w. Possible errors for the different parameters are as follows:

On the average the maximum error for a 6 h or 18 h melt rate was ± 38%, whereas for the larger daily melt rates it was ±20%. This large error range is mainly due to the considerable error of the snow density measurements. It is caused by electronic drift of the gamma probe, due in part to temperature changes in the detector tube. The various terms, used for calculation of SM _M and their absolute errors are tabulated in Table II for two successive periods. Various terms displayed in this table correspond to the snow-profile specifications given in Figure 1. Table II and Figure 1 together illustrate the generally applied measuring and calculation procedure for obtaining the surface and sub-surface melt rate in each time interval. According to Table II the maximum errors of the sub-surface melt rates sometimes unfortunately reach the same order of magnitude as the corresponding measured values thus rendering the measured values questionable for certain periods.

The maximum or average error for a single calculated melt rate is not known. Because the errors of the many components are unknown and because the errors of the measured values could be large, (cf. maximum errors), the goodness of fit of the two curves in Figure 4 cannot be expressed quantitatively.

Table III displays the various melt and ablation rates for daily intervals and the totals for two longer periods. The comparison of the first two columns (SM _C1 , SM _M1 ) shows that the agreement between the daily totals is closer than it was between the 6 h and 18 h values mentioned above, probably due to error compensation. Consequently, the totals for the 9 d and 14 d periods agree to within a few per cent. As a measure of the agreement the calculated daily values are plotted against the measured values in Figure 5. The solid line represents the line of equivalence and the dashed line the regression line (SM _C1 on SM _M1 ).

Fig. 5. Calculated daily melt versus measured melt. The range of maximum error for several measured values is shown by a horizontal dashed line. The solid line represents the line of equivalence and the dashed line the regression line.

This presentation should be regarded as a visualization of the scattering of the values around the line of equivalence and not as an error evaluation in a strict sense, because abscissa and ordinate values are both subject to errors. However, the small standard error of estimate (S _yx = 7.1 mm d⁻¹) and the plotted maximum errors for the measured melt indicate that the agreement between the values is. satisfactory.

The fact that a simple heat-balance approach has a certain potential in describing the single heat exchange processes at the snow surface is demonstrated in Figure 6. It shows the calculated and the measured net vapour fluxes, the latter derived by successive pan measurements. The transfer of mass and energy toward the snow surface is taken as positive. The heat-balance calculations favour a slightly higher net gain of mass than the direct measurements, but the direction and the order of magnitude of the fluxes agree roughly. The pan measurements were not carried out during a period of overcast, drizzle and a mixture of snow and rain (10 to 13 July).

Fig. 6. Calculated and measured hourly vapour flux. Step function is obtained from pan measurements.

The larger differences during the last two days can be explained by the measuring procedure. At the reference location in the plot, the glacier ice was exposed. Consequently, the heat-balance calculations for this period were performed for ice-covered ground (z ₀ = 0.5 mm), while the evaporation measurements were still executed with snow-filled pans, placed in nearby snow patches. Thus the snow-filled pans, subject to rougher surface conditions, showed larger evaporation rates. The totals for the first 9 d were:

This calculation has been executed using z ₀ as sole roughness parameter. During the prevailing fair-weather conditions, the mass balance of the snow-pack was affected by evaporation or condensation processes to a small extent only, although the condensation process supplied 11% of the total absorbed energy, due to its high latent heat.

When comparing the various ablation rates in Table III, large differences are apparent for certain days. These are caused by water storage effects in the lower part of the snow-pack and by sampling errors (e.g. partial loss of liquid water from sample cores). At the base of the snow-pack a fluctuating water table of 10 to 50 mm was present throughout the first 9 d. Sometimes, lateral inflow of water could apparently make up for the actual mass loss on the upper end of the snow-pack. For such conditions, measured daily ablation rates are not comparable with measured or computed melt rates.

Conclusions

Daily melt rates can be determined with a maximum relative error of 20% by evaluating the ice matrix density (in contrast to the total snow density) of the immediate surface and sub-surface layers and by evaluating the decrease in volume. Neglecting the ice-density changes in the sub-surface layer would, on the average, reduce the daily melt rates by 22%. With heavy melt conditions and more precise instrumentation, e.g. a non-drifting, automatically scanning gamma probe, the method could be used even for shorter intervals, i.e. several hours, where all other methods may be subject to large errors due to the delay in liquid water outflow from the snow-pack. Thus, for short intervals, this method alone provides an opportunity to balance detailed heat-balance equations with a mass-balance quantity to sufficient accuracy.

A small but possible effect of the compaction of the whole snow-pack on the results was not taken into account.

The heat-balance approach gave satisfactory results on a daily basis and a close agreement for longer periods. The distribution of the total absorbed energy between the different components for the whole period was as follows: all-wave net radiation 44%, sensible heat 48%, and the latent heat (condensation) 8%. Reference Wendler and StretenWendler and Streten (1969) observed a similar distribution, with the radiative and sensible heat terms interchanged, on an Alaskan glacier in August 1968. This distribution corresponds to the known pattern, often encountered over snow surfaces at low elevations in mid-summer when the convective heat is equal or even exceeds the radiative heat, whereas the condensation process is a rather minor heat source.

It appears that the heat-balance approach described represents a useful method for obtaining melt rates for periods of several days. Applying such an approach, one can avoid the use of a “lumped” melt index like the degree-day factor, and preserve the more physical treatment inherent in heat-balance calculations.