Introduction
It has been observed that several ice shelves off the coast of the Antarctic Peninsula exist close to the climatic limit of variability, taken by Mercier (1978) to be the 0°C summer isotherm. Reference MorrisonMorrison (1990) presented mean annual air temperature records for Faraday station (since 1957) that show an increase of 1.5°C to date. For a further discussion of this subject see Reference Vaughan, Mantripp, Sievers and DoakeVaughan and others (1993). It is expected that rising air temperatures will lead to an increase in melting on the surface of ice shelves and we wish to investigate if this is detectable using space-bourne microwave instruments.
Microwave observations, both passive and active, of snow are sensitive to surface moisture variations and so provide useful climatic and glaciological information concerning the continent-wide annual variation of surface physical state and temperature. However, physical models are required of the surface characteristics to enable a greater understanding of the satellite measurements. Three full years, from July 1987 to June 1990, of SSMI/I data from daily mean grids of Antarctica are used. Brightness temperatures are expressed as T bv, at frequencies of 19 and 37 GHz. Discussed here are observations of variations, both geographically and annually, in the times of onset of melting and refreezing over the austral summer, and how these will serve as direct indicators of rising air temperatures over large areas. Continual monitoring of the freeze-thaw cycle of the surface snow, on an annual basis, will serve as a climatic indicator.
The Data Set
The Defense Meteorological Satellite Program F-8 platform was launched into a sun-synchronous orbit on 20 June 1987 and continues to operate to date. One of the instruments on board is the Special Sensor Microwave/Image (SSM/I), a seven-channel, four-frequency, linearly polarised, passive microwave radiometric system. The instrument measures atmospheric/surface brightness temperatures at 19.3, 22.2, 37.0 and 85.5 GHz. The sensor samples every 12.5km along track at 85.5GHz, every 25 km along track at lower frequencies. Coverage is global except poleward of 87°Ν and 87°S.
The swath data have been processed by the National Snow and Ice Data Centre and gridded at 12.5 km resolution for 85.5 GHz and 25 km for the lower frequencies, on north and south polar stereographic grids. The grid values are the mean brightness temperature over a 24-hour period. A major data gap is present during the period from 3 December 1987 to 12 January 1988, when the sensor was turned off due to instrument overheating caused by solar radiation.
In this study the SSM/I South Polar Region dataset was used providing gridded daily observations on CD-ROM from 9 July 1987 to 30 June 1990. Only the data from the 19 GHz and 37 GHz channels were used as these brightness temperatures are least affected by atmospheric conditions. Single pixel data, over three years, for Τ b19 and T b37, from selected locations on the south polar grid, correspond to points on the principle ice shelves bordering Antarctic Peninsula (Fig. 1).
Observations
In a fashion similar to passive microwave observations of diurnal permafrost melting (Reference EnglandEngland, 1990), it is observed that the spectral gradient, ΔTb = (T b19 — T b37), of snow on the selected ice shelves varies as a function of time on an annual cycle. The spectral gradient over permenently dry snow is principally due to scattering of the snow grains (Reference Chang, Gloersen, Schmugge, Wilheit and ZwallyChang and others, 1976; Reference Zwally and GloersenZwally and Gloersen, 1977). Variations in the spectral gradient, assuming no change in grain size, will be due to changes in the physical temperature profile. Snow at the effective depth of the 19 GHz radiation is at a different physical temperature from that of the lesser effective depth at 37 GHz. During the austral winter the surface snow is cooler than that at depth and the spectral gradient is positive whilst in the austral summer the physical temperature gradient is reversed and the spectral gradient becomes negative.
The time series of the 19 GHz channel over three years, of the data over the George IV Ice Shelf, which is typical for all the ice shelves observed except the Ronne, is shown in Figure 2a. Temperature increases linearly throughout the year until the first melting occurs, indicated by a spike in the brightness temperature. The spike is normally followed by a fall back to the preceding temperature ramp, indicating re-freezing, but a subsequent block of high brightness temperatures indicates near-continual melt conditions. High brightness temperatures are due to the higher emissivity of wet snow over dry snow. Summer is usually followed by a further number of short freeze-thaw cycles. The corresponding spectral gradient (Fig. 2b) shows a sharp rise for each melt incidence, followed by a slow exponential decay as the frozen layers are buried by accumulation or degraded by wind ablation. The start and end of the melt season are determined by a half-peak threshold in the brightness temperature (230 Κ in Fig. 2a), and the start is confirmed through the associated sharp rise in ΔTb.
The contrast to the radio-brightness time profiles for the George VI Ice Shelf, with those for the Ronne Ice Shelf (Fig. 3), shows what occurs on an ice shelf with no significant surface melting. The annual brightness temperature range at 19 GHz is only 15°C (30°C for 37 GHz) and ΔTb is around 15°C, compared with 70°C on George VI. The time series of ΔΤb (Fig. 3b) show no high gradients as seen in Figure 2b, except on 4 January when a freak warm day seems to have occurred, resulting in a partial melting of the surface snow.
Plots of the spectral gradient against T b37 over snowpack reveal that the brightness temperature follows a distinct path through the range of spectral gradients. For locations on the Antarctic plateau, and for southerly ice shelves, such as the Ronne and the Ross, this path is a simple hysteresis track as shown for Vostok (78°28′S, 106°49′E) and Ronne in Figure 4. This effect is a function of the velocity of propagation of the annual temperature minimum, which is in turn a function of the thermal diffusivity of the firn and the frequency of the surface temperature change. The two microwave frequencies are observing at different effective depths in the snow, 37 GHz at about 0.2 m and 19 GHz at about 1 m. However, when the radio-brightness of marginal ice shelves bordering the Antarctic Peninsula is investigated, a new regime in the scatterplot is revealed, together with two distinct physical properties for the observed surface, corresponding to summer and winter. George VI Ice Shelf is typical in this respect (Fig. 5).
The physical change is demonstrated to be due to surface melting through modelling of the dielectric properties of the snow when dry and wet. The transition between these two states is always very rapid (one or two days) during melt in spring, but is characterised during autumn by a series of freeze-thaw cycles. The times of onset of melt and re-freezing are correlated with latitude but are variable from year to year although the shape of the scatterplot remains essentially the same with time and location. The water content of the snow may be determined through modelling of the emission processes (Reference Ulaby, Moore and Fung.Ulaby and others, 1986). Variations in these factors are possible indicators of climatic change.
Microwave Properties of Snow
At a particular frequency, v, the brightness temperature, T b, is a function of the true temperature, T, given by
where e, the surface emissivity, is a function of the frequency and the surface dielectric constant. The scattering albedo, a, of the mdeium is one of the key parameters determining the behaviour of snow emission. It is governed by the ice-particle size relative to the observed radiation wavelength as described by the bulk scattering, Ks, and absorption, ka, coefficients:
At a given frequency, the input parameters necessary to specify K s and Ka for dry snow are the snow density, the radius of the ice particle and the physical temperature of the snow medium. For wet snow we additionally need to specify the liquid-water content, mv. At frequencies above 20 GHz, scattering becomes the domninant component of the total extinction loss of the medium. Thus the magnitude of T b37 compared to T b19 is an indication of the scattering strength of the medium.
When snow melts, the absorption coefficient increases from practically zero for dry snow to a larger value than k s for mv > 1%. Thus, the presence of a very small amount of liquid water in a snow mixture is sufficient to reduce the magnitude of the scattering albedo to a very small value and the apparent temperature dependence on the grain radius is much reduced.
The simple radiative transfer model, based on that of Reference EnglandEngland (1990), has been constructed, using a sinusoidal annual surface-temperature variation. This produces a snow-temperature profile with depth, z, at time t, given by:
where k is the thermal diffusivity given by Reference Carslaw and Jaeger.Carslaw and Jaeger (1959) as 36m2a−1, Ts is the amplitude of the surface-temperature variation and ω/2π is the frequency of the surface-temperature change (once per year).
A linear increase in density from 300 kg m3 at the surface to 500 kg m3 at 10 m depth was assumed and the amplitude of surface temperature variation of 25°C. The mean annual temperature was fixed at 255 Κ such that peak summer surface air temperature would reach 280 Κ with an estimated snow-water content rising to 3% in the surface layers. The emission and transmission from discrete layers to the surface was calculated and summed for all layers. After correcting for scattering attenuation from snow grains 0.2 mm in diameter, and surface transmission at the 50° incidence angle of SMM/I, we can approximate the radiative properties through ΔΤb and T b space as shown in Figure 6.
Discussion
The time track of the radiative properties through ΔT b and T b space always follows a simple oval path when there is no surface melting. Melting, which results in 1–2% by volume of liquid water content in the snow, always produces a second, linear, track on the plot which can be clearly identified. The brightness temperature moves up and down this line as the water content of the snow surface changes with atmospheric conditions.
The numerical model of an arbitrary snow medium, described above, reproduces the general shape of the time tracks when a sinusoidal annual surface temperature variation is assumed. However, it is clear from Figure 2a that the snow temperature does not follow a sine wave, rather it seems to follow a saw-tooth pattern with a rapid drop off in temperature following the end of the summer melting. This being the case, the February-June stretch of the model track in Figure 6 should be much sparser in data points (one point per day) as is the case in region G of Figure 4. The model does not predict the excursions in Figure 4 during melt (region C) and freeze-up (region F). The former would require a more detailed model for how the water content varies with increasing air temperature, and there is also an effect due to the latent heat of fusion to be taken into account in future studies. The scatter of points in region F, where ΔTb is high, seems to be due to the formation of a hard crust with a number of days of surface melt followed by re-freezing at night. The emissivity of re-frozen snow has a strong negative gradient with microwave frequency as the ice grains are much larger than winter grains, and hence scattering loss is increased at higher frequencies (Reference Schanda, Mätzler and Künzi.Schanda and others, 1983) and ΔTb is high. This is supported by the incidental observation that the degree of polarization of the radiation at both 19 and 37 GHz drops significantly at the end of the summer, again indicating that incoherent volume scattering is the dominant effect.
All the marginal ice shelves display plots similar to those shown in Figures 2 and 4, with variations only in the time scheduling of the features and minor differences in the mean annual brightness temperatures. In all cases, with the onset of melting, a discontinuity appears on the time profile of ΔTb as shown in Figure 2b. This corresponds to the gap in the track in Figure 4 between points A and B. The identification of the point of re-freezing is complicated by the presence of crusts, the diurnal thaw and re-freezing cycle and the rate at which new accumulation buries or ablates these crusts. The times for the onset and approximate end of melting for three years of the data are presented in Table 1.
The Ronne Ice Shelf does not exhibit the signature of surface melting of the more northerly ice shelves, however on 4 January 1989 it did show a deviation from the normal hysteresis pattern. Such a deviation indicates a small transient presence of liquid water. If these “freak” periods of melting on the Ronne become more frequent, then this would a further indication of rising air temperatures and changing weather patterns. Like the marginal ice shelves, the Ronne shows moderate deviations in ΔTb during winter and these are probably due to variations in the snow-grain size from old snow to fresh snow following snowfall.
The Peninsula ice shelves can be geographically split between the east (Larsen) and west (Wilkins and George VI) sides of the Peninsula. The main Larsen Ice Shelf seems to have a very regular melt cycle and this is the shortest period of melt of the four. The northern Larsen is more erratic in its pattern, possibly reflecting greater climatic variability with lower latitude. Like the two western ice shelves, it experienced an exceptionally early melt in 1987. Whilst missing data inhibit a detection of the melt that year for the central Larsen, it is clear that this was later than 2 December and hence unrelated to that of the other shelves. The western ice shelves have melt cycles which are closely linked with melt and freeze dates which are practically identical and longer periods of melt than the northern Larsen. The spread of 28 days in the thaw dates across three years indicates considerable regional climatic variability.
Conclusions
Surface melting on snow is detectable using satellite passive microwave instruments, the time of onset of melting is rapid and can be determined to the time resolution of the SMM/I gridded data of one day. Surface melting is detected on all the major Antarctic Peninsula ice shelves but not on the Ronne Ice Shelf. As air temperatures rise the Ronne may incur some melting and the spread of melt area on a year-by-year basis may be mapped. With only three years of data it is not possible to state if the variability in the start and length of time of melting on the ice shelves is typical, but the central Larsen Ice Shelf appears quite stable in these respects.
The passive microwave data display additional features of the melt and re-freeze process which may reveal information about the local accumulation rates as snow builds up over re-frozen crusts.
Acknowledgements
The author acknowledges financial support from NERC-BAS Special Topic grant and the free provision of the SSM/I data from NSIDC. Thanks are also given to S. Laxon and S. Brown of MSSL for software support.