Introduction
The decay of lake ice in spring is an important annual event that profoundly influences the physical, chemical, biological, hydrological and geomorphological processes operating in the lake (Reference Carson and HusscyCarson and Hussey, 1960; Reference Schindler, Welch, Kalff, Brunskill and KritschSchindler and others, 1974; Reference AlestaloAlestalo, 1980; Reference Adams, Gray and MaleAdams, 1981). Lake-ice decay processes at the upper and lower surfaces and inside the ice cover, along with their controlling factors, have been described qualitatively by many authors (e.g. Reference BarnesBarnes, 1960; Reference WilliamsWilliams, 1965, Reference Williams1968; Reference Hobbie and BrittonHobbie, 1973). Detailed assessments of their relative magnitudes are not available, especially for the ice cover of Arctic lakes.
Most ice-decay measurements consider only the change in total ice thickness (Reference ShawShaw, 1965; Reference WilliamsWilliams, 1968; Reference BilelloBilello 1980) and only Reference Scott and RagotzkieScott and Ragotzkie (1961) separated the thickness decrease into upper-and lower-surface components. Internal melt and its effects on ice porosity and albedo have been noted in laboratory and field situations (Reference BarnesBarnes, 1960; Reference KnightKnight, 1962; Reference HobbsHobbs, 1974) and attributed to the absorption of radiation. However, apart from Reference BolsengaBolsenga (1981) and a few others, there has been little effort to examine the behaviour of shortwave radiation in melting fresh-water ice, which is unlike pure ice, winter ice or sea ice where large bodies of information exist.
The simplest approach to modelling the decay of lake ice is the degree-day method (Reference BilelloBilello, 1980; Reference AshtonAshton, 1983) which assumes that air temperature is a good indicator of the available energy and melt processes. The energy balance requires more data, but it deals with the energy exchanges in a more realistic manner and forms the basis of the more comprehensive lake-and river-ice growth and decay models (Reference Wake and RumerWake and Rumer, 1979; Reference Greene and OutcaltGreene and Outcalt, 1985). Although radiation attenuation in the ice cover was included in these models, it was used only to determine the temperature in the ice or water. The porosity changes caused by internal melt were ignored and arbitrary ice densities were used to calculate ice-thickness change. Internal melt was incorporated by Reference AshtonAshton (1985) whose goal was to simulate ice strength but not ice thickness.
For lakes in the High Arctic, the ice is generally 2 m thick and the ice-cover duration often exceeds 10 months. Few systematic observations of the ice-decay processes have been made and there is no comprehensive, energy-balance modelling of these processes. To address these gaps in our information, the present study examines the ice-cover conditions and melt processes occurring on an Arctic lake during the decay period and models ice-cover ablation using an energy-balance approach.
Theory
The growth, thermal regime and decay of a lake-ice cover are controlled by the energy balance of the ice cover:
where is the radiation balance of the ice, Q H and Q E are the sensible-and latent-heat fluxes at the upper ice surface, Q P is the heat added by precipitation, Q w is the heat flux from the lake water to the bottom surface of the ice and dS/dt is the change in heat storage in the ice due to temperature changes as well as the gain or loss of mass. To model ice decay, the energy balances must be determined for the zones where melt occurs, including (1) the air–ice interface, (2) the ice–water interface and (3) the ice interior. In the discussion that follows, a positive flux is considered to be directed towards the ice. The energy balance at the upper ice surface is
where L* is the longwave radiation balance, Q MU is the energy involved in surface melt and Q I is the heat flux into the ice. The net longwave radiation can be considered as part of the surface-energy balance since the incident longwave radiation is rapidly absorbed by the ice. When the ice is isothermal at 0°C during melt, there is no heat conduction into the ice. Given the density of pure ice (ρp¡) and the latent heat of fusion (L F), the surface-melt rate (dh/dt)US (in water-equivalent units) is
The longwave-radiation balance may be obtained from the radiation balance of the ice surface:
where α i is the shortwave albedo of the ice and K↓ is the incident shortwave radiation.
Since the surface of the melting ice cover is fixed at 0°C and 100% relative humidity during the melt period, the aerodynamic bulk-transfer approach can be used to compute the fluxes of sensible and latent heat:
Here, ρ a is air density, C a is the heat capacity of the air, L v is the latent heat of vaporization, ε is the ratio of the molecular weights of air and water, P is air pressure, Uz is the wind speed at height z, T z and T s are the temperature at height z and at the surface, while qz and qt are the vapour pressures at the same locations. The exchange coefficients, D H and D E, are assumed equal and are obtained from
where K is von Karman’s constant. The surface roughness, z 0, can be estimated from the following equation under neutral atmospheric conditions:
where z 1 and z2 refer to the heights at which the wind speeds, u 1 and u2, were obtained.
The exchange coefficients should be modified when applied to stable boundary layers overlying melting ice. This can be achieved through the Richardson number (Ri), defined as
where g is the acceleration due to gravity. Under stable conditions when Ri > 0, Reference Price and DunnePrice and Dunne, (1976) gave the exchange coefficient as
and for unstable boundary layers (Ri < 0)
where b is a coefficient with a value of 10 (Reference Price and DunnePrice and Dunne, 1976).
The final term to be estimated in Equation (4) is the heat brought to the surface by rainfall:
where ρ w is water density, C w is the specific heat of water, T p is the rain temperature which is approximated by the wet-bulb temperature and R is the rainfall intensity.
The energy balance at the bottom of the ice cover is
where Q I is the heat conducted upward into the ice and Q ML is the heat used to melt the underside of the ice. During the melt period, Q I = 0 since the ice is isothermal. Then, the melt rate at the lower ice surface (dh/dt)LS (in water equivalent units) is
The heat flux from the water is determined by the temperature gradient at the ice-water interface but, for operational purposes, this can be approximated by
where k w is the thermal conductivity of water (0.586 W m–1K–1 in still water) and Tzw is the water temperature at a distance zw from the ice–water interface.
Since the ice cover is isothermal during the decay period, thermal conduction can be ignored and the condition of the ice interior will be determined by absorbed solar radiation. The Bouguer-Lambert law describes the attenuation of radiation as it penetrates any medium:
Here, Is and Izi are the irradiances at the surface and at depth zi, while e is the extinction coefficient describing the rate of the attenuation. The internal melt rate of the ice cover (dh/dt)IN is then obtained as
where H is the ice-cover thickness.
Total ice-melt rate (dh/dt, in water-equivalent units) is the sum of the three melt components
Study Site and Field Methods
The study was carried out at Small Lake, about 5 km north of Resolute, Cornwallis Island, N.W.T., Canada (Fig. 1). The lake lies along the coast at an altitude of 5 ma.s.l., has an area of 0.15 km2 and a maximum depth of 10 m. East of the lake is a steep slope which rises to 90 m a.s.l. and the rest of the catchment topography is gently rolling. The lake outlet is dammed by snowdrifts for the first 3–4 weeks of the decay period, causing the lake level to rise about 1 m before it drains (Reference Woo, Heron and SteerWoo and others, 1981).
An experimental site was established on the ice on the northeastern section of the lake where it is deep and a minimum fetch of about 140 m could be maintained. Measurements began when the ice started to melt and ended when the ice cover was about 0.5 m thick and fragmentation began. Air temperature and humidity were recorded on a hygrothermograph at 1 m above the ice. A net radiometer, a pyranometer for reflected shortwave radiation and a sensitive three-cup anemometer were set up nearby, and their outputs were recorded on strip-chart recorders. Air pressure, solar radiation and supplementary data to estimate missing values were obtained from the Atmospheric Environment Service weather station at Resolute Airport located 5 km away.
Manual measurements of the water-temperature profile beneath the ice were made daily with a thermistor array supported against the ice cover by a float for accurate placement. Manual albedo measurements using the pyranometer were made near mid-day, as were measurements of radiation attenuation in ice. A photocell with a 200 nm spectral range centred on 615 nm and calibrated against the pyranometer was used for this purpose. Ice density was obtained by removing a measured volume of ice and weighing it on a triple-beam balance. The surface roughness of the ice (го) was calculated from wind-speed profiles using up to six anemometers to a maximum height of 2.5 m above the ice surface. These last three items were obtained at irregular time intervals.
Ice thickness, ablation of the upper-ice surface and ice-bottom melt were measured daily. A reference datum at the melt site was provided by a Plexiglass tube, fitted with Plexiglass collars to prevent vertical movement, that was frozen into the ice cover before melt. A flexible board was placed on the ice to mark the average position of the ice surface. The vertical distance from the board to the top of the reference Plexiglass stake was measured to provide surface ablation.
Ice thickness was obtained as close to the ablation stakes as possible. A measurement device, consisting of a metal tube with wooden blocks at either end, was hung horizontally beneath the ice on two resistance wires that could be heated if necessary (Reference Ramseier and WeaverRamseier and Weaver, 1975). The whole assembly was then raised with a handle until the blocks touched the lower ice surface. A change in ice thickness was determined by noting the change in the distance between the handle and upper ice surface, as given by the board. The amount of melt at the ice bottom was the difference between the change in ice thickness and the surface ablation. The water level beneath the ice surface, representing the hydrostatic water level, was measured with reference to the Plexiglass ablation stake.
Ice-Decay Computations
The ice cover was divided into layers, 0.02 m thick, and calculations were conducted hourly. Since solar radiation was measured at the Resolute Airport weather station instead of directly over the lake ice, differences in cloud cover inevitably introduced variability into the data used to obtain short-term values of albedo and net longwave radiation. Daily values were calculated instead of averaging such variations.
Internal melt
Hourly melt in the ice-cover interior was calculated sequentially for each layer. The required extinction coefficients were obtained from Equation (16). For the surface layer, Is was set to (1 – α i)K↓ and the calculated I zi was the irradiance for the top of the second layer; this procedure was extended to the other layers in the ice profile. The average extinction coefficient for the entire ice cover decreased from 1.0 to 0.65 m−1 during the melt period, with 0.8 m−1 being a typical value. While these values are consistent with those reported by Reference Goldman, Mason and HobbieGoldman and others (1967) and Reference Hobbie and BrittonHobbie (1973), the average for the whole cover is of limited usefulness, because of the large changes in this coefficient within the ice. The mean value for the porous layer above the hydrostatic water level was 4.0 m−1 and this lies at the low end of the spectral coefficients in the 400–700 nm range obtained by Reference RouletRoulet (1981) (5.0–12.0 m−1 for frozen snow ice) and Bolsenga (1980) (4.8–5.2 m−1 for frozen brash ice).
The extinction coefficient in the ice below the water level averaged 0.3 m−1, a value smaller than Reference BolsengaBolsenga’s (1978) (0.6–0.8 m−1 for melting black ice with surface water) but consistent with the laboratory results of Reference Irvine and PollackIrvine and Pollack (1968) and Reference Grenfell and PerovichGrenfell and Perovich (1981) for pure, cold ice in the spectral region of the photocells used in this study. This suggests that the lower part of a melting lake-ice cover behaves like solid ice.
The wavelength band covered by the extinction coefficient obtained in this study for the surface-ice layer was too narrow to be representative of bulk exdnction coefficient for the wavelengths (400-1400 nm) containing most of the shortwave radiation. For the surface layer of melting sea ice, Reference Grenfell and MaykutGrenfell and Maykut (1977) obtained bulk extinction coefficients of 10.5 m−1 for clear skies and 17.1 m−1 when overcast, with an average of 13.8 m−1. The spectral extinction coefficients for the melting sea ice in the same spectral region covered by the photocell varied from 5.5 to 14 m−1, with an average roughly twice as large as the coefficient obtained in this study (4 m−1). Assuming that the patterns of spectral attenuation for melting sea and lake ice are similar and that the ratio of their extinction coefficients does not vary gready, the bulk extinction coefficient used in the model (7 m−1) was estimated by halving the average bulk-extinction coefficient for sea ice given above.
The bulk-extinction coefficient for the ice below the hydrostatic water level was estimated using the spectral coefficients (е λ) (Reference Grenfell and PerovichGrenfell and Perovich, 1981), the spectral irradiances (Iλ) and albedos (αλ) (Reference Grenfell and PerovichGrenfell and Perovich, 1984)
Here, λ indicates the wavelength in the 400–1400 nm range. The bulk-extinction coefficient calculated in this manner varied from 0.5 m−1 near the ice surface to 0.14 m−1 at a depth of 2.4 m. The mean value of 0.32 m−1 coincided with the observed extinction coefficient (0.3 m−1) and this value was used to describe the extinction of shortwave radiation in the ice below the hydrostatic water level.
To mimic the development of the porous surface layer by internal melt, the bulk-extinction coefficient was increased linearly from 0.3 to 7 m−1 during the first 5d. On a number of occasions late in the melt period, the highly porous layer melted quickly and the ice surface became dark and relatively transparent. To account for this, the extinction coefficient was set to 0.3 m−1 when the albedo decreased below 0.2.
The hydrostatic water level is required to determine when an ice layer becomes part of the porous surface layer, so that the appropriate extinction coefficient can be applied. This was computed by balancing the buoyancy of lower ice layers against the weight of the surface layers. The buoyancy of an ice layer (B expressed as mass per unit area) with thickness (∆zi) is
where ρw, is the water density. The weight of the layer (W) is
To locate the ice layer that contains the hydrostatic water level, the total values of B and W were compared layer by layer. The layer at which the accumulated weight was balanced by the buoyancy contains the hydrostatic water level, and the position of the water level within the layer was determined by linearly interpolating both weight and buoyancy.
The bulk density of the porous ice (p¡) in each layer was determined by adjusting the density of solid ice by the ratio of the energy accumulated within each layer to the energy needed to melt an equivalent layer of solid ice. At the beginning of the study period it was assumed that the ice density was that of pure ice (917 kg m−3).
Surface and bottom melt
To calculate the sensible-and latent-heat flux components of surface ice-melt energy, a value for the surface roughness (Z0) is required. Using measurement periods of 5–15 min over a range of ice-surface conditions, a mean value of 4.5 mm with a standard deviation of 1.5 mm was obtained. This is much larger than 0.15 mm measured for winter ice by Reference LettauLettau (1969) and 0.3 mm used by Reference Greene and OutcaltGreene and Outcalt (1985) for both ice growth and decay. It is comparable to the surface roughness of 2.46 mm for melting glacier ice (Reference MunroMunro, 1989) and is within the range of values for melting snow reported by Reference MooreMoore (1983).
Occasionally, the calculated surface-melt energy was negative when the longwave radiation loss from the surface offset the energy gained or if the air temperature fell below 0°C. In such cases, this energy deficit was accumulated and no surface melt was permitted. The radiation absorbed by the top ice layer and any surface energy gained were used to satisfy the energy deficit before ice melt was resumed.
To calculate the ice-surface lowering, the radiation absorbed was first used to determine internal melting and the new ice-density profile. Other sources of energy were computed using Equation (3) and the total melt energy was converted into ice melt. On the underside of the ice cover, the decrease in ice thickness was computed using Equation (14). In both equations, ρ i of the interfacial layer was substituted for ρ p i.
Field Measurements
Ice-melt conditions in 1980 were similar to those in 1981. Since the 1981 data is of better quality, these results will be emphasized in the following discussion.
Meteorological conditions
Immediately before ice melt, snow melt started when air temperatures rose to the freezing point. The temperatures within the floating ice also increased and within one week, the ice was isothermal at 0°C and the research site was almost free of snow (Fig. 2). This marked the beginning of the study period.
The meteorological conditions for the 1981 ice-melt period are indicated in Figure 3. At the beginning of the melt season, negative net radiation occurred only briefly, when the solar elevation was low. As melt advanced and the ice albedo decreased, the net radiation was positive throughout the 24 h days. Air temperature increased after the melt began as the ground surrounding the lake became bare of snow. Maximum daily temperatures occasionally exceeded 10°C and the minimum rarely fell below freezing. Air temperature and relative humidity fluctuated considerably, depending on whether the wind blew onshore from the cold sea ice or from the warmer bare ground.
Water temperature
Water temperatures measured in Small Lake (Fig. 4) were similar to those reported for other Arctic lakes (Reference Schindler, Welch, Kalff, Brunskill and KritschSchindler and others, 1974). Most of the lake water was isothermal and subject to vertical mixing but, once melt started, a stable layer of meltwater began to accumulate immediately beneath the ice cover. A reduction in the dissolved solids, as indicated by the low specific conductance values in Figure 4, enhanced the stability. Water temperatures at the base of this layer reached 5.5°C approximately half-way through the 1980 ice-decay period due to radiative heating of the water and possible influx of warm water of low specific conductance from the catchment. Vertical mixing induced by density differences and enhanced by wind-driven water soon weakened the stratification of water temperature and specific conductance. Stratification was eliminated 2 weeks before the end of the melt season.
Of particular importance to ice melt is the temperature gradient in the water layer just below the ice. Temperature measurements taken 0.05 m beneath the interface (Fig. 5) indicate that this gradient increased from 8 to 69° C m−1 during the melt period. The marked increase in water temperature mid-way through the melt period in both years was due to increased radiant heating of the water below the thinning ice.
Ice-cover conditions
Wind scour during winter reduced the snow depth to under 0.2 m on most parts of the lake ice. The snow was 0.10–0.15 m thick at the study sites. During the snow-melt phase, this snow cover yielded up to a centimeter of basal ice when the meltwater refroze on the cold ice (Reference Woo and HeronWoo and Heron, 1981).
At the centre of the lake, where the study was conducted, the ice was typically 2.3 m thick. The ice crystals at the surface had essentially vertical c-axes and diameters of about 10 mm. Due to the wedging-out process described by Reference Perey and PounderPerry and Pounder (1958), these crystals were gradually replaced between 0.3 and 0.5 m depth by ice with horizontal c-axes (no preferred orientation) and a vertical α-axis basal plane. This orientation continued to the ice bottom where the ice-crystal diameters reached 0.8 m.
Ice-thickness decrease
Surface ablation
Measured ice-surface ablation rates for three sites are plotted in Figure 6. Initially, the rate of lowering was small but, once surface-ice density decreased, additional melt energy increased the rate of surface lowering, peaking at 106 mm d−1 late in the melt period. Variability of daily ablation rates among three sites reflects not only measurement error but differences in ice conditions at each ablation stake. On a daily basis, the measured differences were usually less than 30% but, over the melt period, differences in total ablation for these three sites was only 5%.
The cumulative surface ablation at site Al in 1980 was 1.13 m or 58% of the ice-thickness loss. Because of slippage by the ablation stakes in 1980, surface ablation was underestimated. A more realistic value of 75% was obtained in 1981, when 1.24 m of ablation occurred (Fig. 7).
Bottom melt
Ice melt at the bottom of the ice cover in the first half of the melt period was typically 2 mm d−1 but individual values fluctuated greatly. Since it was obtained as the difference between change in ice thickness and surface ablation, the cumulative measurement error of these two other variables may exceed the bottom melt itself. When the average melt rate increased to 6.4 mm d−1 in the middle of the study period and to 13.0 mm d−1 near the end, the residual error diminished. The greatest daily loss of ice from the bottom (120 mm) occurred on the last day of measurement and was due to currents, vertical mixing of the water and ice movement. During the 1981 study period, 0.33 m of melt occurred from the bottom of the ice cover, 0.45 m if the last day is also included (Fig. 7).
The 1980 ice-bottom melt was similar to those for 1981 except for 2d of rapid melt that averaged 195 mmd−1. Consequently, the total bottom melt in 1980 was 0.81 m, more than twice the 1981 value. Some of this difference can be attributed to slippage by the ablation stakes which provided the reference datum in 1980.
Internal melt
Ice melt above the water level produced an extremely porous layer during the first week of decay. Ice-crystal boundaries melted and the ice cover had a relatively uniform surface with a foam-like appearance due to the small pores in the crystals. When crystal orientation changed from c-axis vertical to c-axis horizontal, the pores became larger and preferential melt of some of the ice-crystal basal planes roughened the ice surface.
Ice-density profiles obtained during the initial melt period (Fig. 8) showed that internal melt was most intense near the surface. Surface-ice density decreased as internal melt progressed until densities fell below 100 kg m−3. Occasional measurements showed that the density of the surface ice varied between these low values and about 600 kg m−3. Below the hydrostatic water level, ice density was more uniform at about 800 kg m−3 (Fig. 8) but, late in the melt period, density values ranged from 620 to 810kgm-3.
Ice-density profiles altered by internal melt influenced the position of the hydrostatic water level (Fig. 7). The initial decrease in near-surface ice density allowed the ice cover to float higher, thus increasing the distance from the ice surface to the water level. Later, as the ice cover thinned, the hydrostatic water level moved closer to the ice surface.
Albedo
Internal melt influenced the ice albedo through changes in ice density and the hydrostatic water level. Increased surface porosity raised the albedo of bare ice from about 0.15 to 0.5. However, remnant snow and basal ice melting at the measurement sites masked this effect, causing it to appear as only a slight dip in the albedo (Fig. 3). A maximum of 0.56 was reached when the hydrostatic water level was at its lowest beneath the ice surface, and when the surface ice reached minimum densities. There-after, albedo declined in response to thinning of the ice above the water level and fell to a minimum of 0.10. Superimposed on this general trend were fluctuations in albedo caused by changes in the ice density of the surface layers. A prominent albedo decrease in late June (Fig. 3), from 0.45 to 0.20, was due to melt removal of the c-axis vertical crystals which had previously been protecting the underlying c-axis horizontal crystals from internal melting. The ice darkened considerably as this denser, less-porous ice emerged, and this confirmed Reference KnightKnight’s (1962) observation that ice-crystal orientation may influence the albedo. In the next few days, the albedo increased to 0.30 in response to internal melt but higher ice densities prevented it from returning to the earlier values.
Modelled Results
Ice-cover energy fluxes
Equations (3)–(17) were used to calculate the energy fluxes and the daily totals are presented in Figure 9. The absorbed shortwave radiation, which provided 42 (1980) and 41 (1981) % of the energy, was greatest in the early melt period when the ice cover and the porous surface layer were thickest. Both the sensible-and latent-heat fluxes showed an increasing trend throughout the melt period as the atmosphere warmed and became more humid but, on occasions, these could be slightly negative. Sensible-heat flux accounted for 43 and 38% of the energy received by the surface in 1980 and 1981, respectively, while the latent-heat flux provided 6 and 12%. Of the total surface energy, 13 (1980) and 17 (1991) % was used to support the net loss of longwave radiation, while 83 and 87 % was consumed by ice melt. The calculated heat flux from the water was relatively small and increased gradually during the decay period as the water warmed. The heat added to the ice surface by rain was insignificant.
Calculated ice-melt components
The heat fluxes were partitioned into components of melt energy expended on the surface, the ice bottom and inside the ice (Fig. 9). The bulk of the energy was consumed by internal melt, averaging 49% of the melt energy in both years. The maximum calculated daily melt rates were 49 mm d−1 in 1980 and 45 mm d−1 in 1981 but, by the end of the melt period, internal melt declined to approximately 15 mm d−1.
Surface melt accounted for 39% of the total in 1980 and 40% in 1981. Surface melt was limited early in the melt period due to large longwave radiation losses, but later it became the largest melt component as the sensible-heat-flux contribution increased. In 1980, the maximum daily surface melt was 113 mm which was similar to the 108 mm peak value of 1981.
Ice-bottom melt was the smallest in magnitude, accounting for 10 and 12% of the total melt energy in 1980 and 1981.
Comparison of Observed and Computed Results
Internal melt
Changes in ice-skeleton density reflect the amount of internal melt. As shown in Figure 10, the modelled ice density remained above 800 kg m−3 throughout most of the study period, except in the surface layers above the hydrostatic water level where densities less than 100kg m−3 were attained. Throughout the melt period, ice density in this layer fluctuated in response to the amount of radiation absorbed and the surface-ablation rate. Early in the melt period and at the beginning of July, surface melt was relatively small and internal melting greatly reduced the density. When sensible-heat flux increased in late June and mid-July, the low-density surface layers were melted faster than internal melt could replace them and density increased to about 600–700 kg m−3 during these times.
Near the end of the melt period, the computed results suggest that the mean ice density was approximately 780–800 kg m−3 (Fig. 10). Ice-core densities averaged 720 kgm−3 with a range of 620–810 kg m−3. The difference suggests that more melt was occurring in the ice interior than was computed.
Surface melt
A comparison of the daily computed and observed ice ablation for the upper surface in 1981 shows that over half of the points lay outside the 20% error limits. Part of this can be attributed to field-measurement errors. Reference Müller and KeelerMüller and Keeler (1969) suggested that these measurement errors are largely offsetting and become less important over longer periods. However, large short-term errors may cause significant departures in the cumulative values. For example, the 28% error by the model for 1981 was due to overestimation of surface ablation during three periods, each lasting about 2d (Fig. 11). Each time a major deviation occurred in Figure 11, plotting of the computed curve was discontinued and then restarted at the next measured cumulative surface-ablation point. In the first period, 18–21 June, ice density was probably underestimated, resulting in an overestimate of ablation. During the last two periods (26–27 June and 7–8 July), wind-speeds approached 10 m s−1, causing overestimations of sensible-and latent-heat fluxes. When data from these three periods were ignored (dashed line in Figure 11), the measured and computed values became comparable.
Bottom melt
The melt at the bottom of the ice cover is the least significant of the three melt components. The cumulative melt and the calculated melt for 1981 compared favourably (Fig. 12), with the differences rarely exceeding 20 mm until early July. Beyond that point, the model underestimated systematically due to circulation of the lake water (thus invalidating the assumption of still water used in the model) and the movement of the ice cover about the lake.
Discussion
Arctic lake-ice cover tends to be thicker and colder than that in the sub-Arctic, alpine or temperate regions and is composed primarily of very large, interlocking crystals. Melt commences less than 1 month before the summer solstice, so the ice cover experiences 24 h of daylight during decay. The surface-radiation balance is usually positive and, since the ice is not subject to night-time refreezing, melt is essentially continuous during the 6 weeks (or longer) of decay.
During the melt period, the porosity of the surface layers increased greatly and ice densities lower than 100 kg m−3 were achieved. Ice albedo peaked with minimum ice density and decreased along with ice porosity. Reduction in the surface-ice density contributed greatly to the lowering of the ice surface, which accounted for approximately 75% of the change in ice thickness. Melt at the bottom of the ice cover was initially very small but, when the ice fragmented at the end of the decay period, rates of more 100 mm d−1 were observed.
The one-dimensional ice-melt model described above satisfactorily predicted the rate of ice-thickness decrease for almost 80% of the measurement period. The deviations of the model results from the observed conditions can be attributed to inadequacies in both the meteorological variables and the parameterization of the model. In a sensitivity analysis, Reference Greene and OutcaltGreene and Outcalt (1985) determined that their river-ice growth and decay model was less sensitive to the meteorological variables than the extinction coefficient, surface roughness and albedo parameters. Improvements in the estimation of these would increase the accuracy of the model.
The bulk aerodynamic-transfer approach to calculating turbulent-heat transfer is relatively easy to employ and it is commonly used over melting surfaces (Reference MooreMoore, 1983; Reference MunroMunro, 1989). Comparisons with alternative microclimate methods have shown that it performs well (Reference Hay and FitzharrisHay and Fitzharris, 1988; Reference MunroMunro, 1989) but, when the atmospheric and ice-surface conditions deviate from the assumptions required for this approach, the magnitudes of the errors thus created are not known (Reference MooreMoore, 1983).
Such violations of assumptions include the failure of the boundary layer to develop to the height of the instrumentation, the departure from log-linear wind profiles and changes in the aerodynamic roughness of the ice. Resultant errors in the computations of sensible and latent heat could have caused large differences between observed and computed surface melt that occurred on several occasions during the study seasons.
As presendy structured, the model is applicable to Arctic lakes which do not completely freeze to their bed. Through modelling, it is possible to partition ice decay into different components. When the overprediction of surface ablation and the underestimation of ice-bottom melt are accounted for, about one-half of the total energy (52%) was spent on internal melting because of the concentration of radiant energy in the upper part of the ice. The importance of internal melt therefore cannot be ignored in Arctic lake-ice melt models. Approximately 33% of the melt energy was expended at the upper ice surface and about 15% was used for ice-bottom melting during the study period. However, episodes of rapid bottom melt occurred at the end of the melt period, suggesting that this component may become more important when the ice cover fragments and moves frequently.
Acknowledgements
This research was supported by funding from the Natural Sciences and Engineering Research Council of Canada, The Arctic Institute of North America and the Northern Scientific Training Program. Generous logistic support was provided by the Polar Continental Shelf Project, Department of Energy, Mines and Resources. We should like to thank Mr P. Steer, Mr P. Low and Mr D. Orr for their assistance in the field and Mr R, Welch for his cartography.
The accuracy of references in the text and in this list is the responsibility of the authors, to whom queries should be addressed.