1. Introduction

In this paper, we describe and test a new algorithm, which exploits the higher spatial resolution of the 85 GHz channels of the Special Sensor Microwave/Imager (SSM/I) to retrieve higher-resolution daily sea-ice concentration data than are currently provided by other algorithms. The SSM/I sensor, first launched in 1987 as part of the Defense Meteorological Satellite Program (DMSP), scans the Earth’s surface conically with a constant ground-surface incidence angle of 53.1° and is equipped with channels operating at 19.35, 37.0 and 85.5 GHz with both vertical and horizontal polarization, and at 22.235 GHz with vertical polarization alone (Reference Hollinger, Lo and PoeHollinger and others, 1987). Among others, the Bootstrap (Reference Comiso, Grenfell, Lange, Lohanick, Moore, Wadhams and CarseyComiso and others, 1992) and the NASA Team (Reference CavalieriCavalieri and others, 1991) algorithms, which are based on the 19 and 37 GHz channels, are generally used for routine sea-ice concentration retrieval. However, both algorithms suffer from the sensor’s large footprint of 69 × 43 km² (at 19 GHz) and of 37 × 28 km² (37 GHz). The footprint at 85 GHz (15 × 13 km²) allows a much better spatial resolution. Reference Svendsen, Mätzler and GrenfellSvendsen and others (1987) were the first to use frequencies near 90 GHz for sea-ice concentration retrieval. Their results are based on the brightness-temperature polarization difference (BTPD) and have been validated for clear-sky winter (Reference Lomax, Lubin and WhritnerLomax and others, 1995) and overcast summer conditions (Reference Lubin, Garrity, Ramseier and WhritnerLubin and others, 1997).

We use the normalized BTPD (NBTPD) (also called polarization) at 85 GHz instead of the BTPD to minimize the influence of changing physical temperatures of the radiating portion of the sea ice. The other SSM/I channels are not used to retrieve the sea-ice concentration in this study.

Sea ice significantly reduces the exchange of sensible and latent heat as well as momentum between the polar ocean and atmosphere (Reference MaykutMaykut, 1978). Gaining an accurate knowledge of the associated surface fluxes is very important for modeling atmospheric dynamics and thermodynamics with numerical weather-prediction (NWP) models. Over sea ice, the quality of the modeled fluxes is largely determined by the sea-ice concentration, which can be calculated from space-borne remote-sensing data, as well as its thickness and roughness, quantities that are more difficult to estimate from these data. The spatial resolution of space-borne remote-sensing data covers several orders of magnitude, from ∼25 m for the synthetic aperture radar (SAR) to > 25 km for the SSM/I. Though SAR is an excellent source for detailed information on type and structure of a sea-ice cover (Reference Drinkwater and JeffriesDrinkwater, 1998), larger- (hemispherical-) scale geophysical parameters, such as sea-ice concentration obtained from SSM/I data, are more convenient for use in NWP and global circulation models.

The following sections will focus on the new algorithm and possible error sources. The effects of snow cover and intervening atmosphere, which vary both spatially and temporally, are discussed and accounted for by the use of temporal tie points and a radiative transfer model, respectively. The new algorithm is used to calculate daily sea-ice concentration data for the period 1992−98. Examples are compared with independent data for validation purposes.

2. Methods

The basis of the algorithm presented, henceforth referred to as SEA LION, is as follows. The brightness temperature t_p, emitted at polarization p from a partly sea-ice-covered ocean area equal to unity, with the fractions of sea ice c and open water (1 −c), can be written as:

(1)

where the emissivities of open water and sea ice at polarization p are given by ϵ_pw and ϵ_pi, respectively, and t_sw and t_si are the physical temperatures of the sea surface and of the radiating sea-ice portion, respectively. This approach follows that of Reference Svendsen, Mätzler and GrenfellSvendsen and others (1987) but omits multi-year ice since Antarctic sea ice primarily consists of first-year (FY) ice. The NBTPD, which is also used in the NASA Team algorithm, is defined as:

(2)

where t_v and T_h are the brightness temperatures at vertical and horizontal polarization, respectively. The NBTPD calculated from emissivities, which have been measured in situ at 90 GHz in the Weddell Sea (Reference Comiso, Grenfell, Lange, Lohanick, Moore, Wadhams and CarseyComiso and others, 1992), is small over sea ice but quite large over open water (Table 1). Inserting Equation (1) into Equation (2) yields:

(3)

where a is given by

(4)

Table 1. Surface emissivities ϵ_v and e_h and their standard deviations a_v and a_h measured in situ at 90 GHz in the weddell sea, antarctica (Reference Comiso, Grenfell, Lange, Lohanick, Moore, Wadhams and Carseycomiso and others, 1992), and the nbtpd p and corresponding standard deviations (p) as calculated from these measurements

The triplets p_w, t_vw, t_hw and p_i t_vi t_hi are the tie points of open water and sea ice, respectively (section 2.1), which we calculate prior to the retrieval of c (section 2.3). Since Equation (3) is valid for surface measurements only, the use of SSM/I data requires a consideration of the atmospheric effect (section 2.2).

2.2. Atmospheric effects

Compared to the Arctic, the atmospheric effect on SSM/I measurements is much more pronounced in the Antarctic sea-ice zone due to its proximity to the Southern Ocean, which is a substantial source of atmospheric heat and moisture and a site of significant cyclogenesis (Reference King and TurnerKing and Turner, 1997). The increase of the SSM/I brightness temperatures due to emission from atmospheric water, which mainly consists of w and l, is larger at 85 GHz than at the other SSM/I channels (Reference Ulaby, Moore and FungUlaby and others, 1981). Though this increase is less significant over most sea-ice-covered areas due to their high surface emissivities, it becomes larger with decreasing surface emissivities (e.g. over the MIZ: Reference FuhrhopFuhrhop and others, 1998). Figure 1 shows the increase of c due to w and l as calculated from uncorrected 85 GHz SSM/I brightness temperatures with Equation (3) for a calm sea surface (salinity: 34 ppt; surface temperature: 0°C; c= 0%). Over open water, c could increase to 90% or more. Over 100% of cold FY ice (Table 1), this increase (not shown) is still one-tenth of that over open water.

Fig. 1. Increase of cine to w and l as calculated with equation (3) from uncorrected 8.5 ghz ssm/i brightness temperatures over a calm sea surface with c = 0% and the tie points of sea ice and open water as given in the upper left corner.

In order to quantify the effect of w and l, we have modeled brightness temperatures with the radiative transfer model MWMOD (MicroWave MODel) (Reference FuhrhopFuhrhop and others, 1998) for emissivities of 0.44−0.98 in increments of 0.01 and typical values of w and l. For each emissivity, a two-dimensional polynomial fit yields a set of coefficients that allows the subtraction of the quantified atmospheric water effect from the SSM/I brightness temperatures if w, l and the emissivities are known. While w is taken from the operational NWP model of the European Centre for Medium-range Weather Forecasts (ECMWF) over both open ocean and sea ice, this is not possible for l. Over open water, l has been calculated with the method given by Reference Karstens, Simmer and RuprechtKarstens and others (1994), a method which cannot be applied over sea ice. Reference Miao, Johnsen, Kern, Heygster and KunziMiao and others (2000) developed what they call the R-factor method to identify regions where l > 100 g m⁻². We used this method to successfully mask out about 75% of such regions over open water and sea ice. The remaining 25% with l > 100 g m⁻² account for < 5% of the total area covered by the NSIDC grid used. Now we use daily sea-ice concentration maps, which are based on the NASA Team algorithm, as a mask to predefine water- and ice-covered areas. Over sea ice, we set l to its monthly-average value obtained from daily data of l within an approximately 100 km wide open-water area adjacent to the sea-ice edge. These averages vary between 40 and 80 g m⁻² in winter and summer, respectively. This was done considering the high percentage of clouds covering the Southern Ocean (70% according to the results of the International Satellite Cloud Climatology Project (ISCCP)), and the lack of reliable data of l.

Oversea ice, the ratios ofT_vi–dT_vi(O2) orT_hi–dT_hi(O²) and the monthly-averaged ECMWF surface temperatures are taken as the emissivity. The quantities dT_vi(O2) and dT_hi(02) denote brightness-temperatures contributions due to oxygen absorption as quantified with MWMOD. Over open water, the emissivities are altered by the surface wind (Reference Ulaby, Moore and FungUlaby and others, 1981). In particular, v > 10 ms"₁ significantly decrease p at 85 GHz, again causing an overestimation of c if neglected. We used MWMOD to calculate sea-surface emissivities and to model the change of T_v and T_h for typical wind speeds, which have also been taken from the ECMWF model. The emissivities are put into a look-up table. For a given v, this table provides the correct sea-surface emissivity required by the correction for the effect ofw and l on t_v and t_h. The changes of tv and T_h according to v are subtracted from the brightness temperatures after this correction by using a set of coefficients, obtained with a one-dimensional polynomial fit from the modeled brightness temperatures.

3. Results

Figures 2 and 3 show monthly 85 GHz sea-ice tie points averaged over the years 1992−98. Clearly t_vi and T_hi are highly variable throughout the year. Freeze-up coincides well with a sharp increase of t_vi and T_hi in March/April (Fig. 2). The onset of melt is marked by a decrease of t_vi and T_hi from November to January. Remarkable are the low values of T_hi of about 200 K in summer. This corresponds to a surface emissivity of about 0.7 and may be caused by old refrozen coarse-grained snow. The gradual increase of t_vi and T_hi between August and November is probably a result of a growing liquid-water fraction in the snow, which increases the emissivities at both polarizations (Reference Garrity and CarseyGarrity, 1992). Values of p, vary between 0.021 January) and 0.028 (October) and are fairly constant within one standard deviation, which has been calculated from the standard deviations of T_vi and T_hi. Based on these sea-ice tie points, the SEA LION algorithm has been used to calculate daily Antarctic sea-ice concentrations C₈₅ for 1992−98 from NSIDC daily gridded brightness temperatures. Hereafter, NASA Team sea-ice concentrations obtained with the extended weather correction (Reference HeygsterHeygster and others, 1996) are denoted by C_NT, and Bootstrap sea-ice concentrations determined with seasonal coefficients by CBO.

Fig. 2. Monthly 85gh_z sea-ice tie points t_vi andt_hi averaged over the period 1992−98. the error bars denote one standard deviation. subscripts v and h refer to vertical and horizontal polarization, respectively.

Fig. 3. Monthly 85 ghz sea-ice tie point pi averaged over the period 1992−98. the error bars denote one standard deviation.

Figure 4 shows the beginning of the annual sea-ice decay in the Ross Sea in November 1997. More details can be identified in the images on the right side showing c_s5 than in those on the left showing C_NT. Figure 5 shows Operational Line-scan System (OLS) visible images of the Ross/Amundsen Sea region overlaid by the 15%, 60% and 90% isolines of c₈₅ (Fig. 5a) and C_NT (Fig. 5b), on 16 November 1996. About 16 original OLS pixels have been averaged for one OLS pixel (10 × 10 km₂) shown here. The isolines are mapped onto the NSIDC 12.5 × 12.5 km₂ grid. Several coastal polynyas and a decaying sea-ice cover typical for spring can be identified. The 15% isoline of C_NT appears only in one polynya (Fig. 5b) whereas c₈₅ is <15% in almost every polynya (Fig. 5a). This seems to be quite reasonable since, during November, solar radiation accompanied by rising air temperatures stops the sea-ice production in coastal polynyas and keeps them open (Reference Markus, Kottmeier, Fahrbach and JeffriesMarkus and others, 1998). First polynyas within the decaying pack ice (e.g. in the upper left (Amundsen Sea) and the lower right quarter (Ross Sea)) can be identified quite well by the 60% and sometimes even the 15% isoline of c₈5 (Fig. 5a). However, there is almost no correspondence between these areas and the 60% isoline of c_nt (Fig. 5b).

Fig. 4. Evolution of the sea-ice cover in the ross sea, november 1997. left panels: C_NT; right panels: c_s5. sea-ice concentrations <15% have been set to zero.

Fig. 5. Ols visible images overlaid with ssm/i sea-ice concentration isolines of 16 november 1996: (a) c₈5, and(b) C_NT. the south pole is at the upper right corner, and the right (top) image borders are along 180° w (90° w).

Sea-ice concentrations derived from in situ observations from the bridge of the research vessel .nathaniel b. palmer in 1994−98 (C_SHIP) are compared to SSM/I sea-ice concentrations C_SSMI, which have been mapped onto the NSIDC 25 × 25 km₂ grid and rounded to the nearest tenth. Linear correlation coefficients for C_SSMI and C_SHIP He between 0.528 (C₈₅) and 0.576 (C_B0). Average differences C_SSMI – C_SHIP amount to –5% (C_BO), −10% (C₈₅) and −18% (C_NT). The most convincing linear regression is obtained with C₈₅: C₈₅ = 17.0 + 0.7 × C_SHIP

Daily sea-ice areas and extents are calculated from CSSMI for 1992−98 (not shown). The annual and interannual variability of SEA LION sea-ice areas and extents shows reasonable agreement with those obtained from c_bo and C_NT, but for the SEA LION study period sea-ice extents and areas fall below those obtained from c_bO. The extent difference is 0.5 × 10⁶ to 1.5 × 10⁶ km². The areal difference is up to 0.5 × 10⁶ km² in summer and 0.5 × 10⁶ to 1.5 × 10⁶ km² in winter. SEA LION sea-ice extents also fall below NASA Team sea-ice extents (by 10⁶km² in summer and 0.5 × 10⁶ km² in winter). SEA LION sea-ice areas are similar to NASA Team sea-ice areas in summer but exceed the latter by 0.5 × 10⁶ to 1.5 × 10⁶ km² in winter.

4. Discussion and Conclusions

The SEA LION algorithm uses the SSM/I 85 GHz polarization together with monthly sea-ice and open-water tie points, and a weather correction scheme which is based on radiative transfer modeling. It provides daily Antarctic sea-ice concentration data with a spatial resolution of 12.5 × 12.5 km² Daily sea-ice extents and areas obtained from sea-ice concentration data obtained with the NASA Team (C_NT), the Bootstrap (CBO) and the SEA LION (C₈₅) algorithm show reasonable agreement concerning the annual and interannual variability. However, in the regions studied, SEA LION generally provides a smaller sea-ice extent (by about 10⁶ km²) throughout the year. The SEA LION sea-ice areas are similar to those obtained from sea-ice concentrations computed with the NASA Team and Bootstrap algorithms in summer but lie between them in winter.

A comparison of OLS visible images with coincident isolines of c₈₅ and C_NT shows convincing results using SEA LION, particularly concerning the areal coverage by polynyas. Sea-ice concentration gradients provided by SEA LION are better resolved than those derived from the NASA Team algorithm. This may explain why the NASA Team or Bootstrap sea-ice extents are larger than the SEA LION sea-ice extent (more open-water pixels within the pack ice), while the NASA Team and Bootstrap sea-ice areas remain similar to the SEA LION sea-ice area (smaller net amount of sea-ice covered pixels, but higher average sea-ice concentration). We have also compared c₈₅ with 850 ship observations of the sea-ice concentration for 1994−98. The results agree with those obtained with the NASA Team and Bootstrap algorithms.

The quality of the NWP model data, which are used for the correction of the atmospheric effect, and in particular of the cloud liquid-water content l, has a large impact on the retrieval of c₈₅ and may cause significant errors. Further improvements of the atmospheric input parameters are necessary. Monthly sea-ice tie points seem to account for the annual evolution of the microwave signal of almost the entire Antarctic sea-ice cover, but smooth out regional variations. Dividing the ice pack into zones depending on the state of snow metamorphism, and estimating regional sea-ice tie points may be one step towards accounting for these variations. This area requires further research, especially in the light of Figure 2 and when considering the findings of Reference Drinkwater and JeffriesDrink-water (1998) concerning the seasonal backscatter variability of Antarctic sea ice.

The upcoming Advanced Microwave Scanning Radiometer (AMSR) on board the Adeos II and EOS Terra satellites operates at frequencies close to those of the SSM/ I and is additionally equipped with 6 GHz channels. Due to technological advances, its data will allow an improvement of current sea-ice concentration products, mainly due to the enhanced spatial resolution of about 10 × 10 km², and probably in a more economical way than the method presented here, since a simple weather correction seems to be sufficient. The AMSR will provide 89 GHz data with a higher spatial resolution than the low AMSR frequencies. These data can be used to derive higher-resolved and thus more realistic sea-ice concentrations, at least under clear-sky conditions.