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Characteristics of Arctic Sea Ice From Remote-Sensing Data and Their Relationship to Atmospheric Processes

Published online by Cambridge University Press:  20 January 2017

Roger G. Barry
Affiliation:
Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado, Boulder, CO 80309-0449, U.S.A.
Martin W. Miles
Affiliation:
Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado, Boulder, CO 80309-0449, U.S.A.
Richard C. Cianflone
Affiliation:
Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado, Boulder, CO 80309-0449, U.S.A.
G. Scharfen
Affiliation:
Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado, Boulder, CO 80309-0449, U.S.A.
Russell C. Schnell
Affiliation:
Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado, Boulder, CO 80309-0449, U.S.A.
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Abstract

New data on leads and surface-melt phenomena in the Arctic, based on mapping of DMSP visible images, are presented. Lead orientations in the Beaufort Sea are broadly correlated with geostrophic wind direction and show similar synoptic scale patterns. Preliminary results of airborne 1.06 μm lidar transects over Baffin Bay demonstrate its great potential for high-resolution mapping of open-water areas and, in winter/spring, their ice-crystal plumes. Some of these sub-visible plumes are observed to penetrate the Arctic inversion. Snow-melt maps for the entire Arctic prepared for four summer seasons have been used to derive surface-albedo data. From these data the variability of the surface-energy balance is estimated to be equivalent to 0.6 m of ice melt.

Type
Research Article
Copyright
Copyright © International Glaciological Society 1989

Introduction

Fuller understanding of the response of sea ice to seasonal and shorter-term atmospheric forcing through data analysis and numerical modelling is currently hindered by the limited data on ice characteristics and on contemporaneous atmospheric and oceanic conditions. The only ice variable for which substantial records exist is ice extent (Reference BarryBarry, 1986). Information is also needed on ice concentration, ice thickness, and the snow cover on the ice, as well as ice velocity. Our work seeks to provide data on several related parameters, on a variety of space- and time-scales, using a combination of remote-sensing measurements. New sources of data on Arctic leads, polynyi, and surface-melt phenomena derived from DMSP visible satellite images and from airborne lidar measurements are reported. The associated atmospheric conditions are examined using measurements from the Arctic drifting-buoy network (Reference Thorndike and ColonyThorndike and Colony, 1980; Colony and Muñoz, Reference Colony and oz1985).

Large-Scale Characteristics of Open-Water Areas in the Arctic

Mapping from satellite images

The spatial and temporal occurrence of open-water areas (leads and polynyi) are of major significance for the ocean-atmosphere exchange of heat and moisture, especially in winter (Reference MaykutMaykut, 1986). Leads form as a result of tensile failure in the ice, in response to the shear stresses induced by the differential motions of both the air and water. Ideally, leads “form in a band of uniform width, running at right angles to the direction of the major principal stress in the ice sheet” (Reference MellorMellor, 1986, p. 264). Little information exists about the distribution of leads and polynyi on a basin-wide scale. We aim to fill this gap by mapping open-water areas from satellite imagery.

The Defense Meteorological Satellite Program (DMSP) polar-orbiting satellites provide direct read-out images with 0.6 km resolution, covering much of the Canada Basin sector of the Arctic Ocean; these are available in the National Snow and Ice Data Center, Boulder, Colorado. Initially, DMSP visible (0.4-1.1 μm) and infra-red (8-13 μm) images for the sector 70° −85°N, 160°E-130°W were compared with Landsat images from the same date. Landsat images have a nominal resolution of 80-100 m, but enable detection of much smaller high-contrast linear features. It was found that under cloud-free conditions leads ≥300 ± 50 m can be detected on the DMSP images, which, unlike Landsat, are available on a daily basis. Leads of this size represent approximately 1-2% of the lead-frequency distribution, as estimated from submarine sonar data in the Canada Basin (McLaren, in press), but they account for about 20% of the total open-water/young-ice (0-30 cm thick) area and are of major significance for ocean-atmosphere energy fluxes and in terms of large-scale ice dynamics. The time intervals when leads can be mapped from visible images of the Arctic Ocean are generally April-June/July and September-October. Darkness and thick or persistent clouds exclude analysis of the other months, except from infra-red images in the winter when cloud amounts are generally low.

Fig. 1. (a) Distribution of leads ≥300 m in the Beaufort Sea identified from DMSP (0.6 km resolution) visible images for 12 May 1983. (b) Mean sea-level pressure (mbar) for 11 May 1983.

Fig. 2. Lead patterns and corresponding mean sea-level pressure (mbar) patterns in the Beaufort Sea in May of three successive years: (a) 1983; (b) 1984; (c) 1985.

Lead occurrence and orientation are determined from DMSP images (for 1980 and 1982-85) by using a 1° latitude by 5° longitude grid overlay. The lead orientation in each grid cell containing observable leads is calculated trigonometrically as a vector showing the preferred direction and the strength of this preference, following Reference CurrayCurray (1956). The location of leads ≥300 m across is shown in Figure 1 for 12 May 1983, during the season of minimum ice velocity (Reference McLarenMcLaren and others, 1987). It illustrates the general tendency for leads to be arranged roughly parallel to the geostrophic wind direction, as shown by the corresponding mean sea-level pressure map (Fig. 2). The lead patterns, therefore, show similar space scales to atmospheric synoptic systems. Their space-time characteristics are now discussed more fully in relation to surface geostrophic winds.

Relationship to the wind field

To analyze the large-scale relationships between the wind field and the lead orientations more systematically, geostrophic winds have been derived from the daily gridded pressure data provided by the Arctic Ocean Buoy Program (Reference Thorndike and ColonyThorndike and Colony, 1980). The wind fields are referenced to the 1° × 5° grid and correlated with the lead-orientation values in each grid box using wind values for each of the 2 d preceding the date of the lead observation. Wind directions and lead orientations are both recorded in 15° intervals. In this manner, each grid cell has a pair of angular values: (1) lead orientation (ϕ) and (2) wind direction (θ), and the difference δ = ϕ − θ.

There is no generally agreed upon measure of directional/vector correlation; several different correlation statistics have been recently proposed, both non-parametric and parametric (Klink, unpublished). For this research, an appropriate correlation statistic was selected for its ability to include: (1) a bounded range, (2) rotational dependencies, and (3) ease of interpretation, as suggested by Klink (unpublished). For this research, the fact that the lead “direction” has two values, ϕ and ϕ + 180°, is also important.

The correlation statistic used is essentially that prescribed by Reference BatscheletBatschelet (1981), where r B is the correlation coefficient:

A large r B value indicates that ϕ is strongly dependent on θ whereas, if r B approaches zero, the two variables are uncorrelated. This statistic can be modified to give the direction of the rotation (angular co-variation) and direction of a mean resultant correlation vector (Reference Klink and WilmottKlink and Willmott, 1985). These correlation procedures provide an indicator of the variability of lead patterns which may be attributable to atmospheric forcings. For the case illustrated in Figure 1, the correlation coefficients (averaged over 62 grid points) are 0.80 (day -2), 0.91 (day -1), and 0.90 (day 0). Of 15 cases for which 3 d statistics could be obtained, three show a high correlation (rB > 0.82) between lead orientation and wind direction, ten are moderately correlated (rB = 0.57-0.82), and two are weakly correlated (rB < 0.57). These classes correspond to >66, 33-66, and <33% of the variance explained. The results are summarized in Table I.

There are several parameters of interest in the analysis.

The response time of the orientation of major lead patterns to changes in the wind field can be determined. It is evident from several weekly series of images that lead orientations may change noticeably within 24 h of changes in the wind field; but in other cases they exhibit substantial persistence of orientation. For example, during March-April 1980, the lead pattern remained essentially unchanged for several weeks, in this case, ice concentration was high, and ice velocities were low despite the presence of fairly persistent anti-cyclones. As a result of synoptic variability in the atmosphere, there is also considerable inter-annual variability in lead orientation. Figure 2 illustrates this for dates in early May from three different years. An initial objective of the study was to determine whether there might be sufficient regularity in lead orientation at given seasons such that statistics of lead widths and keel spacings, derived from submarine sonar measurements of under-ice topography, could be interpreted more quantitatively. At present, it is generally unknown whether submarine transects are perpendicular to or sub-parallel to ice openings, for example. The results of this work indicate substantial temporal variability in lead patterns. Consequently, it would be necessary to have almost synchronous aircraft or satellite imagery for a given submarine transect in order to compare it with submarine sonar measurements of leads and ridge keels. Nevertheless, our results suggest that a first approximation of the field of major fracture orientations could be “modelled” given appropriate geostrophic wind data.

The seasonal variation in the observed relationships of leads and wind fields is also of interest. In general, the winter months are expected to be less likely to show a strong relationship between lead patterns and wind fields, as a result of the compact sea-ice conditions in winter. Motion in the Beaufort Gyre is low in April, for example, despite the fact that the intensity of the Arctic anti-cyclone reaches a maximum in this month (Reference McLaren, Serreze and BarryMcLaren and others, 1987). However, Table I shows little or no seasonal variation in the directional correlation coefficients. There are also no consistent patterns in the timing of the maximum correlation between wind direction and lead orientation over the 3 d and no apparent seasonal differences. The angles of rotation of the leads from the wind direction (averaged over the array) are also highly variable (Table I). In winter-spring, the mean angular values are near zero during days 1 and 2 prior to the date of the lead map and −34° (counter-clockwise rotation of the lead from the geostrophic wind) on the same day. In summer-fall, leads are rotated 12° clockwise from the wind and are more strongly rotated 2 d prior. However, large samples are needed to produce an adequate characterization of the relationships.

Table I Correlation of geostrophic wind and lead orientation from case studies. correlation coefficient (r B) and angle of rotation (αB) are shown for winds during the 3 d preceding the lead observation. (mean values are from z-score conversion.) αB > 0 indicates that the lead is rotated clockwise from the wind direction

Reference Thorndike and ColonyThorndike and Colony (1982) have reported that over 70% of the variance of ice velocity in the central Arctic is explained by the geostrophic wind. The results thus far indicate that lead patterns are also moderately correlated with the geostrophic wind, although there are many complicating considerations. The frequency, intensity, and persistence of cyclonic and anti-cyclonic disturbances are additional factors contributing to lead characteristics, as are the antecedent lead patterns and other ice characteristics (for example, ridges, grounded ice, etc.). Where the observed relationship between leads and winds is weak, the over-riding factor is the continuing state of the antecedent lead conditions due to the near absence of ice motion over all or part of the study area.

Airborne Lidar Observations of Open-Water Areas

A new source of high-resolution information on the sizes of leads and other open-water areas is provided by airborne lidar measurements. Near-infra-red (1.06 μm) wavelength lidar is highly sensitive to particulates due to the large ratio of paniculate/molecular back-scatter. This enables open-water areas to be detected in the winter half-year by their plumes of moisture and ice crystals. A lidar instrument was flown in the eastern Canadian Arctic in January 1984 and March-April 1986 in conjunction with the Arctic Gas and Aerosol Sampling Program (AGASP). The lidar surface resolution (“footprint”) is on the order of 1 m, but at a typical air speed there is a pulse about every 30 m, yielding an “effective” resolution of 30 m. However, our initial work has been performed by manual analysis of the facsimile plots of the same data (Reference MorleyMorley, 1987), which permit only more generalized mapping of features S200 m. These records have been analyzed and compared with suitable cloud-free visible and infra-red DMSP satellite images and with operational sea-ice charts and weather data for corresponding dates.

The results of a preliminary statistical analysis of the available analog data for northern Baffin Bay for a total track length of 1300 km indicate a modal value for width of open-water areas of c. 200 m, the limit of discrimination of the facsimile plots, and a median width of approximately 1 km (Fig. 3). These results may be compared with those obtained in previous research in the study region (Reference SteffenSteffen, 1987). His studies for 1800 km of flight line in the North Water area of Baffin Bay indicate that 90% of the ice fractures (leads and refrozen leads) are less than 600 m wide, and fractures greater than 1.2 km are very rare. Steffen found a log-linear decrease in frequency of larger leads, whereas Figure 3 shows a higher frequency of wider fractures. Comparison of the flight tracks with a visible AVHRR image for 4 April 1986 confirmed that major leads were present in Baffin Bay and permitted the coastal polynyi to be excluded from the analysis. The discrepancy may reflect seasonal differences, since regional differences between the North Water area and the main part of Baffin Bay seem unlikely in view of Steffen's inter-comparison of encounters with fractures versus fracture width in Baffin Bay, North Water, M'Clure Strait, and Lancaster Sound (Reference SteffenSteffen, 1987, fig. 4). Our future analyses will make use of the digital lidar data collected in the Arctic in 1984, yielding higher resolution and permitting more precise statistics to be obtained.

Fig. 3. Frequency histogram of fracture sizes in northern Baffin Bay based on aircraft lidar data (1.06 μm) for three flights 2-9 April 1986. The lower cut-off is due to the resolution of the facsimile plots. Data are grouped in 100 m size classes.

In addition to compilation of statistics on open-water areas, an estimation from the lidar data of water and heat fluxes from openings in the ice is of considerable interest for the assessment of surface and atmospheric energy budgets and maintenance of the Arctic inversion. Figure 4 illustrates a plot of lidar data over Baffin Bay on 18 April 1986. The lidar penetrates thin ice and accordingly refrozen areas as well as openings are identifiable, except below stratus cloud. The depth of penetration of the lidar is not at present known; however, the returns shown from below the surface on Figure 4 should be regarded as having an arbitrary vertical scale. Microphysical measurements by the aircraft showed that the plumes are composed of ice crystals, whereas the stratus is composed of water droplets which completely attenuate the lidar signal. Ice-crystal plumes extending beyond 2.5 km altitude are apparent. In some cases, the plume on an image may be associated with leads or small polynyi not directly below the flight track. Therefore, correlation of these records with satellite images requires a synchronous pass and locational precision of the flight track.

Fig. 4. Analog record from airborne lidar over Baffin Bay, 18 April 1986. The horizontal lines are at 0.5 km intervals above the surface; the scale below the surface is arbitrary. Stratus and ice-crystal plumes are evident; leads and polynyi are identified by the clear areas below the surface.

Figure 4 and other examples show that ice-crystal plumes may penetrate the Arctic inversion, transporting substantial amounts of heat and moisture into the lower troposphere, up to at least 4 km altitude. This is contrary to the prevailing view that most of the heat remains within the stable boundary layer or is returned to the surface down-wind of leads. Field measurements, taken during the AIDJEX Lead Experiment (Reference Andreas, Paulson, Williams, Lindsay and BusingerAndreas and others, 1979), show that the turbulent-heat fluxes from leads can exceed 400 W m−2 for sensible heat and 130 W m−2 for latent heat, which is released as the water vapor rapidly forms ice crystals in the cold air. These heat fluxes provide the necessary buoyancy for the upward motion of plumes.

Following compilation of sufficient statistics on lead occurrence from the available lidar data and future flight programs, it should be feasible to develop improved estimates of the contribution of turbulent-heat fluxes to energy budgets in the Arctic on a regional scale during winter and spring.

Snow Melt on Arctic Sea Ice

The temporal and spatial progression of the melting of snow cover on the sea ice has been mapped manually from DMSP visible images for the entire Arctic Ocean at 3 d intervals for four summer seasons based on tonal contrasts and textural patterns ( Reference Scharfen, Barry, Robinson, Kukla and SerrezeScharfen and others,1987). The methods used to carry out the mapping for four ice-surface classes and to convert the information into estimates of surface albedo are described in the paper cited.

Examination of the results of each of the 4 years (1977, 1979, 1984, and 1985) shows considerable inter-annual and spatial variability in the timing of snow melt and the subsequent ponding and drainage of the ice between early May and mid-August. This is illustrated by the spatial progression of melt in 1977 and 1979, the years of greatest difference in overall timing so far examined (Reference Scharfen, Barry, Robinson, Kukla and SerrezeScharfen and others, 1987). In both 1977 and 1979, the monthly pressure fields for May and June show mean high pressure over the Arctic Basin. However, June 1977 had a greater frequency of days with anti-cyclone centres and, as a result, the central Arctic experienced cloud-free conditions in about 20% of days in 1977 compared with only 8% in June 1979 (Reference Robinson, Kukla and SerrezeRobinson and others, 1985). This would greatly augment the solar radiation reaching the surface. In each year studied, the melt of snow cover begins in the Barents and Kara Seas and more or less simultaneously in the southern Beaufort and Chukchi Seas, progresses along the Arctic coast of Asia, and then extends towards the American side of the North Pole.

Estimated surface albedos over the entire Arctic Basin are most variable in June with, for example, a monthly average of only 0.58 in 1977 compared with 0.66 in 1979 (Table II). In three out of five sub-regions, the difference in June albedo between these 2 years was ≥0.1. The Eurasian marginal seas exhibit even larger variability in May and June. The potential significance of these differences is indicated by Figure 5 showing the mean surface-energy budget for the central Arctic and the effects of the calculated range of albedo values. Figure 5 also shows how the presence of snow cover limits the fraction of incoming solar radiation that is absorbed at the surface and causes a 1 month lag in the peak of absorbed radiation behind that of the incoming radiation. The calculated seasonal difference in surface net radiation between maximum and minimum albedo values for the central Arctic amounts to approximately 160 MJ m−2. Hypothetically, this is sufficient for melting 0.66 m of saline ice. The percentage increase in absorbed energy between maximum and minimum values of surface albedo amounts to 19% for the central Arctic, but reaches 30% over the East Siberian-Laptev Seas (Table II). This implies that ice conditions in this sector in late summer can be expected to undergo large inter-annual variations.

Table II Incoming solar radiation (after Reference Marshunova, Fletcher, Keller and Olenicoffmarshunova, 1966), maximum and minimum surface albedos of four seasons (from scharfen and others, Reference Scharfen, Barry, Robinson, Kukla and Serreze1987) and corresponding values of absorbed solar radiation (MJ/m2)

* North-west North Atlantic: solar radiation values averaged for 85°N/60°E and 85°N/0°E.

Fig. 5. Surface-energy budget components for the central Arctic (based on Reference MaykutMaykut, 1986). K↓ = incoming solar radiation, K(1 - α) = absorbed solar radiation, In = net infra-red radiation, and Rn = net radiation. The bars denote ranges corresponding to the maximum and minimum albedos observed over 4 years.

Discussion

Sea-ice models aim to describe ice drift and the build-up and decay of ice thickness (Reference HiblerHibler, 1985). Typically, simulations of the variations of ice-edge location and ice compactness are performed. For verification of climate models incorporating an interactive ocean with a sea-ice cover, data are needed on both mechanical and thermodynamic processes in the ice (World Climate Research Programme, 1987). The essential ice variables are: concentration (and edge position) determined every 3 d on a 30 km grid, ice thickness, and daily ice velocity on a 500 km grid. Ice concentration can now be determined from multi-frequency passive microwave data. However, there is still need for refinement and testing of the algorithms, especially in the marginal ice zone where weather systems may mask the ice signature and during the summer when melt phenomena complicate the interpretation (Reference Maslanik and BarryMaslanik and Barry, 1989). The attainable accuracies, unless supplemented by other data, are c. 10% for first-year ice and 30% for multi-year ice. Ice velocity can currently be determined from the Arctic buoys and in the 1990s this information will be greatly augmented by synthetic aperture radar (SAR) data to be provided by the European and Japanese Earth resources satellites. Data on ice draft are collected by upward-looking sonar systems in submarines, but only limited amounts of such data have so far been released and analyzed (Reference Wadhams and HomeWadhams and Home, 1980; Reference Bourke and GarrettBourke and Garrett, 1987; McLaren, in press). The spatial distribution of ice thickness, even for seasonal averages, cannot yet be reliably stated. Such statistics are important in terms of both the model dynamics and for thermodynamic calculations of heat exchange.

The products currently being prepared, as described above, provide a basis for interim model testing. For example, Reference Ross and WalshRoss and Walsh (1987) have simulated snow-melt progression. Starting from late spring snow-depth estimates, based on a climatological assessment using observations made at coastal and island stations for 1977 and 1979, and using actual climatic forcings for these years, they simulated the decay of the snow cover for the Arctic Ocean sectors defined by Reference Scharfen, Barry, Robinson, Kukla and SerrezeScharfen and others (1987). They were able to reproduce both inter-annual contrast between these two seasons, illustrated earlier, and spatial differences on the rate of decay of the snow cover. Extension of the snow-melt mapping to another six seasons is in progress, in order to provide a more adequate sample of inter-annual variability and to permit verification of simulated conditions for additional years.

We suggest that the statistics on the spatial occurrence of leads and other openings in relation to various synoptic forcings will also be useful for examining the dynamic characteristics of sea-ice models. The rapidity, or otherwise, of change in patterns of leads in response to wind-velocity changes for varying conditions of ice compactness provides information on the appropriate rheology for different regions or stages of the seasonal cycle.

The climatic implications of the ice characteristics (lead fraction and surface albedo) in terms of ocean and ice-atmosphere energy fluxes have been illustrated in general terms. However, the contribution of leads to the turbulent-energy flux into the boundary layer and, more importantly, to heat and moisture transfer into the troposhere above the Arctic inversion requires more specific analysis. Such an analysis is currently in progress.

Conclusions

New sources of data on leads in Arctic sea ice and on surface-melt phenomena are provided by satellite and air-borne remote sensing. The orientations of major leads in the Beaufort Sea mapped from visible-band satellite images are shown to be broadly correlated with geostrophic wind direction and have similar synoptic scale patterns. Preliminary results of airborne 1.06 μm lidar transects over Baffin Bay demonstrate its great potential for high-resolution mapping of open-water areas and, in winter/spring, for identifying their ice-crystal plumes. Some of these sub-visible plumes are observed to penetrate the Arctic inversion. Snow-melt maps for the entire Arctic, prepared for four summer seasons, have been used to derive surface-albedo data. The possible contributions of such data sets to verification and improvement of numerical sea-ice models are discussed. In addition, both the albedo and the lead data will enable assessments of the surface-energy balance over ice to be significantly extended in spatial and temporal contexts. For example, the variability of the surface-energy balance for the central Arctic attributable to variations in timing of snow melt on the ice is estimated to be equivalent to 0.66 m of ice melt.

Acknowledgements

This work was supported by the U.S. Office of Naval Research under a University Research Initiative Program contract N00014-86-K-0695. We thank M. Neary for drafting and M. Strauch for word processing. DMSP images are archived at the National Snow and Ice Data Center, University of Colorado.

References

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Figure 0

Fig. 1. (a) Distribution of leads ≥300 m in the Beaufort Sea identified from DMSP (0.6 km resolution) visible images for 12 May 1983. (b) Mean sea-level pressure (mbar) for 11 May 1983.

Figure 1

Fig. 2. Lead patterns and corresponding mean sea-level pressure (mbar) patterns in the Beaufort Sea in May of three successive years: (a) 1983; (b) 1984; (c) 1985.

Figure 2

Table I Correlation of geostrophic wind and lead orientation from case studies. correlation coefficient (rB) and angle of rotation (αB) are shown for winds during the 3 d preceding the lead observation. (mean values are from z-score conversion.) αB > 0 indicates that the lead is rotated clockwise from the wind direction

Figure 3

Fig. 3. Frequency histogram of fracture sizes in northern Baffin Bay based on aircraft lidar data (1.06 μm) for three flights 2-9 April 1986. The lower cut-off is due to the resolution of the facsimile plots. Data are grouped in 100 m size classes.

Figure 4

Fig. 4. Analog record from airborne lidar over Baffin Bay, 18 April 1986. The horizontal lines are at 0.5 km intervals above the surface; the scale below the surface is arbitrary. Stratus and ice-crystal plumes are evident; leads and polynyi are identified by the clear areas below the surface.

Figure 5

Table II Incoming solar radiation (after marshunova, 1966), maximum and minimum surface albedos of four seasons (from scharfen and others, 1987) and corresponding values of absorbed solar radiation (MJ/m2)

Figure 6

Fig. 5. Surface-energy budget components for the central Arctic (based on Maykut, 1986). K↓ = incoming solar radiation, K(1 - α) = absorbed solar radiation, In = net infra-red radiation, and Rn = net radiation. The bars denote ranges corresponding to the maximum and minimum albedos observed over 4 years.