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Glaciological study in Terra Nova Bay, Antarctica, inferred from remote sensing analysis

Published online by Cambridge University Press:  20 January 2017

Massimo Frezzotti
Massimo Frezzotti*
Affiliation:
ENEA CRE Casaccio, P.O. Box 2400, 00100 Roma A.D., Italy
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Abstract

Analysis of satellite images (Landsat 1 MSS, 4 TM and SPOT 1 XS), of U.S. Navy aerial photographs (TMA) and of U.S.G.S. maps has made it possible to assess a number of parameters relating to the surface dynamics (between 1956 and 1990) of eight ice tongues and of two ice shelves in the Terra Nova Bay area. The study shows that between 1960–63 and 1972–73 there was a decided decrease in the areas of some of the tongues and shelves: −53 km2 for the Aviator Glacier Tongue and −124 km2 for the Nansen Ice Sheet. On the other hand, the areas generally increased in the period 1972–73 to 1988. An exception to this situation is the small Hells Gate ice shelf whose area diminished by 1.15 km2 between 1956–57 and 1988. The calculated surface velocity of the ice tongues shows that they increase from the grounding line to their outer limit. Values of longitudinal strain rate generally increase from the grounding line to just after the start of the ice tongue, after which they diminsh proceeding towards its outer limit. Integration of the areal values with radio-echo sounding data has enabled the ice discharges of the southern flow of the David Glacier (12km3a−1) and of the Aviator Glacier Tongue (0.62 km3 a−1) to be calculated. Furthermore, on the basis of the data available, basal melting values of between 25 cm a−1 and 100 cm a−1 are deduced for these two ice tongues, and bottom freezing values of 20 cm a−1 for the Drygalski Ice Tongue. Different spectral responses of the glacial areas have made it possible to discriminate ablation areas from those of accumulation and to differentiate various typologies of ice (glacier ice, melt lake ice, and sea ice formed at the ice shelf-ocean interface).

Type
Research Article
Information
Annals of Glaciology , Volume 17 , 1993 , pp. 63 - 71
Copyright
Copyright © International Glaciological Society 1993

Introduction

The Italian Antarctic research program has been operating in the Terra Nova Bay area (Victoria Land) since December 1985. This area is on the boundary between two zones with different morphological and glaciological characteristics (Fig. 1). To the north are the mountains of northern Victoria Land with their alpine-type morphology and glacial cover in the form of névés and local glaciers (Aviator, Campbell, Random Hills and Tinker) which are not fed by the East Antarctica ice sheet. These glaciers discharge into Wood Bay and Terra Nova Bay, forming ice tongues. To the south the coast is characterized by ice tongues fed by small glaciers (the Clarke and Larsen glaciers) which drain local nunatak areas partly fed also by the peripheral part of the inland ice sheet. The major outlet glaciers of the area, David, Reeves and Priestley, which drain part of Dome Circe and of the Talos Dome (Reference DrewryDrewry, 1983) having an area of approximately 250000 km2, unite in Terra Nova Bay. The Reeves and Priestley outlet glaciers, joining together, form the Nansen Ice Sheet (the name given on the U.S.G.S. map, though it is an ice shelf). Hells Gate is a small ice shelf, floating in Terra Nova Bay, situated between the Northern Foothills and Vegetation and Inexpressible islands.

Ice shelves and ice tongues play an important role in the dynamics and mass balance of Antarctic ice sheet. Different authors (Reference Williams, Ferrigno, Kent and SchoonmakerWilliams and others, 1982; Reference SwithinbankSwithin-bank, 1988; Reference MacDonald, Ferrigno, Williams and LucchittaMacDonald and others, 1989; Reference Bindschadler and ScambosBindschadler and Scambos, 1991} have shown that reliable parameters concerning flow characters of these features (flow rate, areal and ice front variation, lateral spreading etc.) can be obtained by analysis and comparison of satellite images and air photos which have been taken several years apart. The ice tongues and ice shelves of Terra Nova Bay range in area from tens of km2 (Larsen and Random Hills ice tongues, Hells Gate ice shelf) to about 2000km2 (Nansen Ice Sheet, Drygalski Ice Tongue).

Fig. 1. Sketch map of Terra Nova Bay and Wood Bay area redrawn on the basis of U.S.G.S topographie maps of Antarctica Reconnaissance Series. Legend: 1: Floating ice shelves, ice tongues and glacier tongues; 2: Fast and bay ice; 3: Ice-free area.

The katabatic winds from the East Antarctica ice sheet are the most significant climatic factor in the Terra Nova Bay area (Reference Bromwich and KurtzBromwich and Kurtz, 1984). These winds blow mainly along the valleys of the David, Reeves and Priestley glaciers. Their force and persistence, mainly in winter, causes the formation of persistent annual polynya in Terra Nova Bay (Reference Kurtz and BromwichKurtz and Bromwich, 1983). Moreover, these winds are the principal element acting on the surfaces of the glacier bodies, causing high surface ablation rates with the formation of areas of blue ice, windscoops and snowdrifts.

Materials and Methods

Aerial photographs and satellite images of Terra Nova Bay area have been acquired since 1955 and 1972 respectively. Aerial photographs were taken by the U.S. Navy with the Trimetrogon system (TMA) between 1955 and 1963 and they have been used by the U.S. Geological Survey and the National Science Foundation to compile maps of the Antarctica Reconnaissance Series at the scale 1 :250 000 for the Ross Sea sector. In this study, the Sequence Hills, Mount Murchison, Reeves Névé, Mount Melbourne, Mount Joyce and Relief Inlet sheets have been used. The satellite images were recorded by Landsat 1 MSS (1972 and 1973), by Landsat 4 TM (1988 and 1990) and SPOT 1 XS (1988, 1989 and 1990). Landsat 1 MSS is a first-generation satellite, with images having an normal spatial resolution (pixel size) of about 80 × 80 m and four spectral bands. SPOT 1 XS and Landsat 4 TM are second-generation satellites showing high quality geometrical definition with a spatial resolution of 20 × 20 m and 30 × 30 m respectively. SPOT 1 XS has three spectral bands and Landsat 4 TM has seven spectral bands.

With the use of Landsat 4 TM satellite images (62/113 and 62/114 of 17 January 1990; Fig. 3) and SPOT 1 XS images (25/547, 27/547, 28/549 and 26/550 of 19 December 1988; 24/544 and 25/546 of 2 December 1989 and 20/545, 21/544; 21/547 and 23/546 of 12 January 1990; Fig. 2), two geo-referenced mosaics were created (Reference Frezzotti and YoshidaFrezzotti, 1992; forfecchia and Frezzotti, 1991), identifying on the images the geodetic network of P.N.R.A. (ITALIANTARTIDE) and the Survey Control Stations of the U.S. Geological Survey Maps. Geo-refcrencing was carried out by rectifying the images in a Lambert Conformal Conic cartographic projection (Standard Parallel 72°40′ and 75°20′, WGS 72) equal to that of U.S.G.S. maps, using a linear conversion matrix with a RMS of less than two pixels. Taking these mosaics as references, the other satellite images (Landsat 1 MSS 64/112 and 64/113 of 28 November 1972; Landsat 1 MSS 64/113 and 64/114 of 2 January 1973; Landsat 4 TM 60/ 114 of 13 December 1988) were rectified using a linear conversion matrix with a RMS of under one pixel.

The satellite images and the maps of the ice tongues and of the ice shelves corrected in this way were analyzed and compared by digital techniques. The different geographical positions of the glacial features (ice fronts, snow drifts, crevasses, ice dolines etc.) during different years allowed evaluation of variations of surface parameters, the positions of the ice fronts and the surface velocities (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a;Reference Frezzotti and Yoshida Frezzotti, 1992). The main error in flow rate determinations results from the geometric resolution of the satellite (Landsat 1 MSS 80 × 80 m, Landsat 4 TM 30 × 30 m, and SPOT 1 XS 20 × 20 m) and from imprecise positioning of points caused by uncertainties in identifying identical details of the features in the two images, as Reference Orheim and LucchittaOrheim and Lucchitta (1987) point out.

To investigate the ice shelf Hells Gate, we utilized the following vertical U.S. Navy photographs: TMA 325 F32, no. 70–72 (3 December 1956), TMA 365 F32, no. 289–292 (10 December 1957); TMA 2851 V, no. 62–64 (6 November 1985); TMA 2852 V, no. 103–106 (6 November 1985). On these we established scale with a detailed topographic survey of the dirt cones occurring at the surface of the ice shelf at Hells Gate west (Reference BaroniBaroni, 1990). The relative positions of the dirt cones and of the ice front were delimited on the basis of the distance from reference points on land (Inexpressible Island to the west and Northern Foothills to the east). The measurements were repeated on enlargements (×5) of both the 1956–57 and 1985 images. This procedure allowed the measurements of the flow rate and the variation of the ice front between 1956–57 and 1985 original photographs (9 × 9 in). Other measurements have been obtained by comparing a subscene of the SPOT 1 XS (27/547, 19 December 1988; Fig. 6) with aerial photograph (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a).

All the elaborations were carried out using the hardware and software instruments of EDI (ENEA DIGITAL IMAGERY) system.

Ice Tongues and Ice Shelves

Aviator, Campbell, Random Hills and Tinker

The local Aviator, Random Hills and Tinker glaciers end in ice tongues in Wood Bay (Fig. 2), whereas Campbell Glacier ends in Terra Nova Bay (Fig. 1). These glaciers have accumulation basins (Fig. 1) varying in size between a few tens of km2 (Random Hills, 76km2) and some thousands of km2 (Aviator Glacier, 7300 km2, Campbell Glacier, 4000 km2, Tinker Glacier, 1400 km2). The basins of these glaciers reach and exceed 3000 m (Mount Hewson, approximately 3720 m) and they develop mainly at heights of more than 1000 m (80% of the Campbell glacier basin area develops at heights of more than 1000 m). The Random Hills and Campbell glaciers have their grounding line and the start of the ice tongue more or less coinciding, while the Tinker and Aviator glaciers float for about a quarter of their length (Fig. 1).

Fig. 2. Subscene of mosaic of SPOT 1 XS images (Reference Borfecchia and FrezzottiBorfecchia and Frezzotti, 1991) in false color (RGB:3, 2, 1) showing the Wood Bay area. Legend: 1: Ice front in 1989 (SPOT 1 XS); 2: Ice front in 1972 (Landsat 1 MSS); 3: Ice front in 1963 (U.S.G.S. maps); 4: Radio-echo sounding in meters (Reference Engelhart, Schomburg and ThyssenEngelhart and others, 1989).

The analysis of the position of the ice fronts (U.S.G.S. 1963, Landsat 1 MSS 1972, SPOT 1 XS 1988–89) has shown that the Campbell Glacier Tongue retains the same extent over time (Table 1) but not the morphology of its ice front. Such a situation could be explained by assuming that constant annual iceberg calving offsets the ice discharge. The Aviator, Random Hills and Tinker ice tongues floating in Wood Bay present significant variations in extent and morphology in the course of time (Fig. 2 and Table 1): certain elements typical of the morphology of the ice cliffs of the ice tongues are retained for tens of years (Reference Frezzotti and YoshidaFrezzotti, 1992). For these ice tongues we have to assume periods of more than ten years of constant growth, interspersed by phases in the course of which the breaking off of icebergs reduces their area significantly. The different behaviour of the ice tongues in the two bays should be linked with the winter polynya present in Terra Nova Bay, pointed out by Reference Kurtz and BromwichKurtz and Bromwich (1983). The presence of the polynya prevents the formation of fast and bay ice around the Campbell Glacier Tongue, enabling the wave motion and the sea currents to break up the ice tongue into small icebergs. The presence of fast and bay ice through most of the year in Wood Bay permits instead a better protection and conservation of the ice tongues, which then break up when there are intense storms.

The annual flow rates of these ice tongues (Table 1) have been calculated over an average of 17 years (Landsat 1 MSS of 1972 and SPOT 1 XS of 1989) at 31 points for Aviator, five points for Random Hills and eight points for Tinker. For the Campbell Glacier Tongue it has been possible to calculate the annual flow rate (Table 1) at 33 points on two high-resolution images taken at an interval of 12 months (SPOT 1 XS in December 1988 and December 1989). In the northern sector of the initial part of the Aviator Glacier Tongue, the calculated flow rates range from 119 to 172 × 5 m a with longitudinal strain rate values of 4.1–6 × 10−3a−1. In the southern sector of the ice tongue, instead, flow rates of 145–149 × 5m a−1 and longitudinal strain rates of 1.8 × 10−3a−1 have been calculated. The values of the velocity (175−185 × 5m a−1) and of the longitudinal strain rate (1.1–1.5 × 10−3 a−1) in the second part of the ice tongue are homogeneous in both sectors. The rift observed in the northern part of the ice tongue (Fig. 2) seems to be linked with this velocity difference. Such behaviour is probably the consequence of an abrupt change in direction of the glacier just before becoming a tongue.

Table I. Surfiàal parameters and ice discharge

Integration of surface parameters (flow rate, width) with ice thickness values (estimated by means of the height of the surface of the ice tongue above sea level, assuming hydrostatic equilibrium) has enabled the ice discharge to be assessed for the following ice tongues: Campbell (0.4 km3 a−1) Random Hills (0.01 km3 a−1) and Tinker (0.063 km3 a−1). For the Campbell and the Random Hills ice tongues, as the start of the tongues coincides with the grounding line, the ice discharge corresponds to that of the glacier. The value of the ice discharge of the Campbell Glacier is in line with the value estimated by Zanon (1988). Along the final part of the Aviator Glacier (Fig. 2) some thicknesses of the ice have been measured by means of radio-echo sounding (Reference Engelhart, Schomburg and ThyssenEngelhart and others, 1989) These values agree with those estimated on the ice tongue, taking the height of the ice front above sea level, assuming hydrostatic equilibrium. Using the width, flow rate and ice thickness values, it has been possible to assess the ice discharge at a number of points of the Aviator Glacier Tongue. At the Cape Sibbald section, the ice discharge is about 0.62 km3 a−1 and decreases 10 km away to 0.55 km3 a−1, about midway along the ice tongue to 0.35 km3 a−1 and about three-quarters of the way along it to 0.30 km3 a−1. Since the morphology of the ice tongue is very well conserved, the ice discharge loss must be correlated with the phenomena of basal melting. In Terra Nova Bay area average accumulation values of about 15 cm a−1 of water equivalent (Reference Meneghel and SmiragliaMeneghel and Smiraglia, 1991) have been measured. On the basis of morphological observations which suggest higher value of snow accumulation in Aviator Glacier Tongue than Terra Nova Bay area, we may assume a snow accumulation of about 20 cm a−1 water equivalent. Using these snow accumulation and ice discharge values and the surface parameters (width, flow rate, etc.), it is possible to assess an average basal melting of approximately 20–25 cm a−1, at least equal to the snow accumulation value.

Clarke and Larsen

Fig. 3. Mosaic of Landsat 4 TM images (62/113 and 62/114 of 17 January 1990) in false color (RGB: 4, 3, 2) showing the Terra Nova Bay area between Nansen Ice Sheet and Clarke Glacier. Legend: 1: Ice front in 1988 (Landsat 4 TM); 2: Ice front in 1973 (Landsat 1 MSS); 3: Ice front in 1960 (U.S.G.S. maps); 4: Radio-echo sounding in meters (Scott Polar Research Institute, in Reference SwithinbankSwithinbank, 1988).

The ice tongue of Clarke Glacier floats between the Cape Irizar and Drygalski Ice Tongue, and the ice tongue of Larsen Glacier floats between the Nansen Ice Sheet and the Drygalski Ice Tongue (Figs 1 and 3). The Clarke and Larsen glaciers drain local nunatak areas partly fed by the peripheral part of the inland ice sheet. The geographical positions of the Clarke and the Larsen ice tongues enable fast and bay ice to remain for tens of years, protecting the ice tongues against wave motion. The morphology of their ice fronts (Fig. 3) can be recognized atan interval of tens of years (1960 U.S.G.S. maps, 1972–73 Landsat 1 MSS, 1988–90 Landsat 4 TM). The annual flow rates (Table 1) have been calcualted over the average of 16 years (Landsat 1 MSS 1972, Landsat 4 TM 1988) at ten points for Clarke and at five points for Larsen. For the ice tongue of Larsen Glacier the ice discharge has been evaluated as 0.082 km3 a−1 (Reference Frezzotti and YoshidaFrezzotti, 1992).

David—Drygalski

The Drygalski Ice Tongue is the floating tongue of David Glacier (Figs 1 and 3), the largest outlet glacier of northern Victoria Land, draining an area of the East Antarctica plateau measuring 224 000 km2 (Mclntyre in Reference SwithinbankSwithinbank, 1988). The David Glacier is formed by the convergence of various flows under an icefall, David Cauldron. At this point it is possible to assume a variation in the trend of the substratum (Reference McIntyreMclntyre, 1985) with the stream entering a deep fjord-like valley, according to the hypothesis already made by Reference SwithinbankSwithinbank (1988). The variation in trend of the substratum must also coincide with the grounding line as downstream of the icefall transverse depressions are present, characteristic of a rapidly diverging flow in floating glacier and ice tongue. Reference Steed, Drewry and CraddockSteed and Drewry (1982) point out that the David Glacier coincides with a subglacial trench which crosses the Transantarctic Mountains, linking the Ross Sea basin with the internal Wilkes subglacial basin. As the major part of the David Glacier basin rests below sea level (Reference DrewryDrewry and others, 1983), this glacier must be regarded as a marine based one (Reference OrombelliOrombelli, 1991). The supply of the David Glacier comes from two main flows, a northern one from the Talos Dome and a southern one from Dome C (Reference DrewryDrewry, 1983)!

The Drygalski Ice Tongue retained the same ice front morphology (Fig. 3) between 1960 (U.S.G.S. map) and 1990 (Landsat 4 TM), as already pointed out by Reference HoldsworthHoldsworth (1985) and Reference JacobsJacobs (1987). The area of the ice tongue increased by some 27.5 km2 a between 1960 and 1973, and by some 15 km2 a−1 between 1973 and 1990, without any evident detachment of icebergs (Reference Frezzotti and YoshidaFrezzotti, 1992). The annual flow rates (Table 1) have been calculated over an average of 15 years (Landsat 1 MSS 1973, Landsat 4 TM 1988) at 75 points and over the average of 13 months (Landsat 4TM, 1988–90) at 137 points (Table 1 and Fig. 4). These values are in fair agreement with those measured by Reference HoldsworthHoldsworth (1985; 730 ± 36 m a−1 at about 50 km from the coast), Reference MacDonald, Ferrigno, Williams and LucchittaMacDonald and others (1989; 670–1070 m a−1 and average velocity 840 m a−1) and Reference SwithinbankSwithinbank (1988; 580 m a ). The southern flow has a thickness upstream of the icefall of 2530 m (Scott Polar Research Institute, in Reference SwithinbankSwithinbank, 1988). This flow has a width of about 10 km in the David Cauldron (Figs 3 and 4), remaining constant to the start of the ice tongue (Mount Neumayer-Hughes Bluff section). The northern flow has a width of approximately 13 km at the grounding line (Mount Priestley section; Fig. 4) and at the confluence with the southern flow the width is reduced to about half (5.75 km) and to one-fifth (2.5 km) at the start of the ice tongue (Mount Neumayer-Hughes Bluff section). The velocity of southern flow in the Mount Priestley section is 550 ± 30 m a−1. At the same section the northern flow has a velocity of 136 ± 30 m a−1.

Fig. 4. Velocity, width and thickness of David Glacier-Drygalski Ice Tongue.

The different surface parameters (flow rate and width) show that the southern flow is the main one and that its ice discharge must definitely be more than that of the northern one. Analysis of the annual flow rates calculated in the period (December 1988-January 1990) show an increase in the rate from the grounding line to the terminal part of the ice tongue (Fig. 4). Using the regression curve of the annual velocity the longitudinal strain rates have been calculated. In the southern flow a constant decrease may be observed in the longitudinal strain rate going from the grounding line (5 × 10−3 a−1) to the terminal part of the ice tongue (2.7 × 10−3 a−1). The transverse velocity component (vy) of two flows increases significantly corresponding to the start of the ice tongue (from 25–108m a−1 to 80–191 m a−1), after which it decreases (25-80 m a−1) at 45 km from the start of the ice tongue. The vy component of the southern flow is generally greater than that of the northern flow, which is in accordance with the lateral spreading trend observable on the satellite images (Figs 3 and 4).

When the glacier leaves the valley its width increases from 13 km (Mount Neumayer-Hughes Bluff section) to 22.75 km at a distance of 45 km, as already reported by Reference SwithinbankSwithinbank (1988). The northern flow doubles its rate from the start of the ice tongue (from 259 ± 30 m a−1 to 501 × 30 m a−1; Fig. 4), within a few km attaining the velocity of the southern flow (580 × 30 m a−1). The longitudinal strain rate of this flow between the grounding line and the start of the ice tongue is between 27 and 58 × 10−3 a−1, rising to values of 140 × 10−3 a−1 only 3 km away from the start of the ice tongue. This value decreases to 8.8 × 10−3 a−1 at 7 km from the start of the ice tongue, and then decreases to values similar to the southern flow (4.2 × 10−3 a−1) at 10–15 km from the start of the ice tongue. The opening of the characteristic rifts in the northern part of the ice tongue (Fig. 3) must be correlated to this difference in the velocity and longitudinal strain rate of the two flows.

Some ice thicknesses have been measured by radio-echo sounding in 1974–75 (by the Scott Polar Research Institute, in Reference SwithinbankSwithinbank, 1988) along the David Glacier-Drygalski Ice Tongue (Fig. 3). We may assume that the thicknesses of the ice body, at the same distance from the grounding line, do not change in a significant way between 1974–75 and 1988–90. If we assume that the flow rate and the thickness are homogeneous along the section, it is possible to calculate the ice discharge at five points of the southern flow of the David Glacier-Drygalski Ice Tongue from the grounding line (about 12 km3 a−1) to 2/3 of the ice tongue (2.07 km3 a−1). The ice discharge between the grounding line (12 km3 a−1) and the second point measured, about 30 km distant, shows a reduction of approximately 50% (6.35 km3 a−1). Between this point and the next one, about 40 km away, there is a constant ice discharge (6.35 km3 a−1–6.43 km3 a−1). At the two successive points where measurement was possible, the ice discharge decreases (5.4 km3 a−1–2.07 km3 a−1). The ice discharge value of 12 km3 a−1 of the southern flow of the David Glacier is fairly well in agreement with the value of 14 km3 a−1 of the balanced discharge assessed for the David Glacier by Mclntyre (in Reference SwithinbankSwithinbank, 1988).

On satellite images (Landsat 1 MSS and Landsat 4 TM) it is possible to observe an area of blue ice between the central part of the David Glacier (Mount Priestley section) and about 40 km from the start of the ice tongue. This indicates the presence of ablation areas, resulting from deflation and sublimation induced by katabatic winds blowing from the plateau. Downstream and upstream of this area, along the David Glacier-Drygalski Ice Tongue, it can be observed that the surface consists of snow and that the glacial morphologies are covered by snow.

In the Terra Nova Bay area average ablation values have been measured for the blue ice areas of about 20 cm a−1, and accumulation values of about 15 cm a−1 of water équivalant (Reference BaroniBaroni, 1990; Reference Frezzotti and YoshidaFrezzotti, 1992; Reference Meneghel and SmiragliaMeneghel and Smiraglia, 1991; personal communication from Reference Meneghel and SmiragliaM. Meneghel, 1991). Using these values for the accumulation and ablation areas of the David Glacier-Drygalski Ice Tongue, the surface parameters and the ice discharge values previously calculated, the following basal melting/freezing values may be derived (Fig. 5): 45cm a−1 of melting between the grounding line and the second RES point about 30 km away; 20 cm a−1 of basal freezing, at least equal to the surface ablation value caused by the katabatic winds, between the second RES point and the following one about 40 km away; melting of 40 cm a−1 between this RES point and the fourth one, increasing to 100 cm a−1 two thirds of the way along.

Basal freezing phenomena in the Terra Nova Bay area have already been reported by various authors for the Nansen and Hells Gate ice shelves (Reference BaroniBaroni, 1990; Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a; Reference SouchezSouchez and others, 1991). Baroni (1991) derives for the western ice shelf part of Hells Gate an average basal freezing value of 12–25 cm a−1. The melting/freezing processes at the base of the David Glacier-Drygalski Ice Tongue must be dominated by deep thermohaline convection, as already assumed for the nearby ice shelf Hells Gate by Reference SouchezSouchez and others (1991).

Fig. 5. Schemetic representation of David Glacier-Drygalski Ice Tongue. Legend: 1: Ice derived from snowfall on the floating glacier and ice tongue; 2: Sea ice that freezes to the base of the footing glacier and ice tongue; 3: Sea ice; 4: Flow rale; 5: Basal melting; 6: Basal freezing; 7: Ice discharge; 8: Ablation induced by katabatic winds; 9: Snow accumulation; 10: Katabatic winds.

This theory has been advanced by Reference RobinRobin (1979) and expanded by several authors (Reference Lewis and PerkinLewis and Perkin, 1986; Reference Jenkins and DoakeJenkins and Doake, 1991). The deep circulation beneath the floating part of David Glacier and the Drygalski Ice Tongue is driven by dense, saline water formed as a result of salt rejection from sea-ice production. Reference Kurtz and BrornwichKurtz and Bromwich (1985) estimate that the Terra Nova Bay polynya produces 10% of the sea ice generated over the entire Ross Sea shelf.

Nansen Ice Sheet

The Nansen Ice Sheet has an area of approximately 1800 km2 (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a), and is characterized at its front by characteristic rift morphologies, with the formation of large wedges (Fig. 3). These forms are due to the different velocities of the flows from the Reeves and Priestley glaciers (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a). Analysis of the satellite images (Table 1 and Fig. 3) and of the aerial photographs has shown that between 1963 and 1972 an iceberg of about 170 km2 became detached (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a) and that between 1972 and 1988 the ice shelf increased in area by a value equal to the annual rate of area increase due to ice discharge (3.5km2a−1). The annual velocities have been calculated over the average of 16 years (Landsat 1 MSS 1972, SPOT 1 XS 1988) at 40 points (Table 1). The surface velocity increases both at the ice front and in the central portion of the Nansen Ice Sheet. It is possible to recognize different sectors of the ice shelf characterized by different surficial velocity. The portion of Nansen Ice Sheet fed by the northern sector of Reeves Glacier moves faster than both those fed by the sou thern sector of the same glacier and by Priestley Glacier (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991 a). This velocity difference could be related to the friction of the ice shelf against Tarn Flat and Inexpressible Island and to the slopes on the ice surface of the portions fed by the Reeves Glacier (3 m km−1) and Priestley Glacier (2 m km−1). The thickness of the ice front has been estimated as about 165 m by means of the height of the ice cliff above sea level, assuming hydrostatic equilibrium, and thus the ice discharge at the ice front about 0.62km3a−1 (Reference Frezzotti and YoshidaFrezzotti, 1992). F rom the satellite images (Fig. 3) it is possible to observe that about 40% of the shelf area (approximately 720 km2) consists of blue ice (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a). This is a consequence of the ablation induced by the katabatic winds from Reeves and Priestley valleys (Reference Bromwich and KurtzBromwich and Kurtz, 1984). On the Terra Nova Bay area average values of surface ablation induced by katabatic winds of 20 cm a−1 have been noted (Reference BaroniBaroni, 1990; Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a; personal communication from M. Meneghel). Considering these values it is possible to calculate a surface ablation of the ice shelf of about 0.15km3a−1 (Reference Frezzotti and YoshidaFrezzotti, 1992).

Hells Gate

Hells Gate is a small ice shelf more than 70 km2 (Fig. 6). The southernmost portion of the ice shelf, south of the latitude of the northern edge of Inexpressible Island, consists of a deflation area about 29 km2 wide. The area is affected by a strong, persistent katabatic wind which blows from the Reeves Glacier (Reference Bromwich and KurtzBrornwich and Kurtz, 1982; Reference BaroniBaroni, 1990; Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a). The ice shelf is fed by bottom freezing (12–25 cm a−1), as shown by Reference BaroniBaroni (1990), Reference Baroni, Stenni and IacuminBaroni arid others (1991b) and Reference SouchezSouchez and others (1991).

Fig. 6. Subscene of SPOT 1 XS image (27/547, 19 December 1988) in false color (RGB: 3, 2, 1) showing Hells Gate. Legend: 1: Ice front in 1988 (SPOT 1 XS); 2: Ice front in 1985 (TMA 2851); 3: Ice front in 1956–57 (TMA 325 and 365); 4: Flow rate.

The satellite image (Fig. 6) shows that the ice shelf of Hells Gate is divided into three sectors (western, central and eastern) by ice-cored moraines (Reference BaroniBaroni, 1990). The western and central sectors consist of flows from the Nansen Ice Sheet and from the southern slopes of the Northern Foothills, while the eastern sector is fed by local accumulations of snow. The central sector consists of two flows. Analysis and interpretation of the satellite images of the ice shelf, integrated with geochemical works on the ice and by glaciology (Reference BaroniBaroni, 1990; Reference Baroni, Stenni and IacuminBaroni and others, 1991b; Reference SouchezSouchez and others, 1991), have made it possible to discriminate (because of the different spectral response in the near-infrared and the visible bands) snow (white in Fig. 6), glacier ice (blue), the ice of melt lake (dark blue) and marine ice formed at the underside of the ice shelf (green). The boundary between the marine ice and glacier ice, well identifiable on the satellite images, is conditioned by the ablation induced by the katabatic winds. Assuming a constant average wind ablation value over the whole area of the ice shelf, the position of the boundary between the marine ice and the glacier ice in the various parts depends on the different velocities of the flows.

From the trend of this boundary it is observed that the velocities diminish from the central part toward the edges; the central area, with a higher velocity, includes the central-western flow and the eastern part of the western flow. The velocities have been calculated by analyzing the aerial photographs, over an average of 28–29 years (TMA 325, 365 and 2851), at 12 points, and they are between 2.9 and 11.9ma−1 (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a). These values are in accordance with those obtained by Reference BaroniBaroni (1990) on the basis of the available C14 calibrated dates of the shells collected on the surface of the ice shelf.

The area of Hells Gate diminished by about 0.56 km2 between 1956–57 and 1985, and by some 0.59 km2 between 1985 and 1988 (Table 1 and Fig. 6): the total reduction was about 1.15 km2 (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a). According to Reference OrombelliOrombelli (1990) the ice shelf Hells Gate has retreated several hundred meters since 1912, when a first topographic sketch map was drawn by Reference PriestleyPriestley (1923). Taking into account an ice discharge of about 1.2 × 106 m3 a−1 the mean annual loss by iceberg calving ranges from 2.5 to 3.5 × 106m3a−1 over the period 1956–88. Furthermore, considering a conservative mean ablation rate about 20cm a−1 (Reference BaroniBaroni, 1990), the ice lost at the ice shelf surface is 5.8 × 106m3a−1. The resulting total ice lost by iceberg and surficial ablation can be estimated between 8.3 and 9.3 × 106m3a−1 against an ice discharge value of 1.2 × 106m3a−1 (Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a).

Concluding Remarks

The analysis of satellite images and aerial photographs of Terra Nova Bay area allowed us to characterize and describe ice shelves and ice tongues. Albation and accumulation areas as well as the pattern of surficial flow have been identified. The different spectral response of the glacial surfaces has made it possible to discriminate the ablation areas from those of accumulation and to differentiate various types of ice. Comparison of different images and photographs, taken at intervals of several years, has enabled the variation in size, the velocities and the spreading of the main ice tongues and ice shelves to be assessed. By integrating these data with those of RES and of ablation/accumulation, a number of ice discharge and bottom melting/freezing parameters have been evaluated. In addition, the importance of the strong, persistent katabatic winds in the dynamics of the ice shelves and ice tongues of Terra Nova Bay is evidenced.

Analysis and interpretation of the satellite images of the ice shelf Hells Gate, integrated with geochemical work on the ice and glaciology (Reference BaroniBaroni, 1990; Reference Baroni, Stenni and IacuminBaroni and others, 1991b; Reference SouchezSouchez and others, 1991), have made it possible to discriminate (Fig. 6) due to their different spectral response in the near-infrared and the visible bands snow, glacier ice, the ice of melt lake and marine ice formed at the ice shelf-ocean interface.

The analysis of the satellite images and aerial photographs shows that between 1960–63 and 1972–73 there was a definite decrease in some of the areas of the ice tongues and the ice shelves (−53 km2 for the Aviator Glacier Tongue and −124 km2 for the Nansen Ice Sheet), whereas there was an increase in the period between 1972−73 and 1988. An exception to this general situation is the small ice shelf Hells Gate, whose area diminished by 1.15 km2 between 1956–57 and 1988. According to Reference OrombelliOrombelli (1990) this ice shelf has retreated several hundred meters since 1912, when a first topographic sketch map was drawn by Reference PriestleyPriestley (1923).

The calculated surface velocities of the ice tongues and of the ice shelves area between 3 m a−1 (Hells Gate) and 912 ± 30 m a −1 (Drygalski Ice Tongue). Analysis from the velocities of the ice tongues shows that they increase from the grounding line to their outer limit. The longitudinal strain rate values generally increase from the grounding line to a short way past the start of the ice tongue, after which they decrease toward the outer limit. The Drygalski Ice Tongue presents considerable lateral spreading at the start, going from a width of 13 km inside the valley to about 22.5 km halfway along the ice tongue. The opening of rifts in the ice tongues (Aviator and Drygalski) and in the ice shelves (Nansen) is due to the different velocity and longitudinal strain rate of the flows that form these glacial bodies.

Ice discharge calculated for the glacial bodies of the Terra Nova Bay area is between 12 km3 a−1 for the southern flow of the David Glacier and 1.2 × 106 m3 a−1 for Hells Gate. For the David Glacier-Drygalski Ice Tongue and for the Aviator Glacier Tongue it has been possible to assess a number of basal melting values (from 20 to 100 cm a−1), while for David-Drygalski a bottom freezing of 20 cm a−1 has been assumed, at least equal to the surface ablation value induced by the katabatic winds. The presence of bottom freezing in Terra Nova Bay, already pointed out by other authors (Reference BaroniBaroni, 1990; Reference Baroni, Frezzotti, Giraudi and OrombelliBaroni and others, 1991a; Reference Baroni, Stenni and IacuminBaroni and others, 1991b; Reference SouchezSouchez and others, 1991) is due to the deep circulation below the ice shelves and the ice tongues led by the dense saline waters formed as the result of salt rejection from sea ice production (Reference Lewis and PerkinLewis and Perkin, 1986; Reference Jenkins and DoakeJenkins and Doake, 1991). Reference Kurtz and BrornwichKurtz and Bromwich (1985) estimate that the polynya of Terra Nova Bay, casued by katabatic winds, produces 10% of the sea ice generated over the entire Ross Sea shelf. Moreover, the action of the katabatic winds induces a strong ablation on the surface of the glacial bodies with values as loss from surface of between 0.15 km3 a−1 (Nansen Ice Sheet) and 5.8 × 106km3a−1 (Hells Gate). For the last named, although the ice shelf is receding, the wind ablation is five times greater than the ice discharge at the ice cliff and represents 60–70% of the volume of ice lost by the ice shelf between 1956 and 1988.

Acknowledgements

This work has been carried out as part of the Programma Nazionale di Richerclie in Antartide (ITALIANTARTIDE) and was supported financially by ENEA through a joint research program on Antarctic Earth Science with the University of Siena (Italy). The glaciological research is coordinated by Prof. Giuseppe Orombelli.

References

Baroni, C. 1990 The Hells Gate and Backstairs Passage ice shelves (Victoria Land, Antarctica). Mem. Soc. Geol. Ital., 43, 1988 123144.Google Scholar
Baroni, C. Frezzotti, M. Giraudi, C. Orombelli, G.. 1991a. Ice flow and surficial variation inferred from satellite image and aerial photograph analysis of Larsen ice tongue, Hells Gate and Nansen ice shelves (Victoria Land, Antarctica). Mem Soc. Geol. Ital., 46, 6980.Google Scholar
Baroni, C. Stenni, B. Iacumin, p.. 1991b. Oxygen isotopie composition of ice samples from the Hells Gate and Backstairs Passage ice shelves (Victoria Land, Antarctica): evidence of bottom freezing. Mem Soc. Geol. Ital., 46, 4548.Google Scholar
Bindschadler, R.A. Scambos, T.A.. 1991 Satellite–image–derived velocity field on an Antarctic ice stream. Science, 252(5003), 242246.Google Scholar
Borfecchia, F. Frezzotti, M.. 1991 Satellite image mosaic of the Terra Nova Bay area (Victoria Land, Antarctica). Mem. Soc. Geol. Ital., 46, 521523.Google Scholar
Bromwich, D.H. Kurtz, D.D.. 1982 Experiences of Scott’s Northern Party: evidence for a relationship between winter katabatic winds and the Terra Nova Bay polynya. Polar Rec, 21(131), 137146.Google Scholar
Bromwich, D.H. Kurtz, D.D.. 1984 Katabatic wind forcing of the Terra Nova Bay polynya. J. Geophys. Res., 89(C3), 35613572.Google Scholar
Drewry, D.J., ed. 1983 Antarctica: glaciological and geophysical folio. Cambridge, University of Cambridge. Scott Polar Research Institute. Google Scholar
Engelhart, H. Schomburg, O. Thyssen, F.. 1989 Radio–echo sounding in north Victoria Land, Antarctica. Geol. Jahrb., Reihe E, 38, 111117.Google Scholar
Frezzotti, M. 1992 Fluctuations of ice tongues and ice shelves derived from satellite images in Terra Nova Bay area, Victoria Land, Antarctica. In Yoshida, Y., ed. Recent progress in Antarctic earth science. Tokyo, Terra Scientific Company.Google Scholar
Holdsworth, G.. 1985 Some effects of ocean currents and wave motion on the dynamics of floating glacier tongues. Antarct. Res. Ser., 43, 253271.Google Scholar
Jacobs, S.S. 1987 Ice fronts and icebergs in Ross and Weddell seas. Antarct. J. U. S., 22(5), 9194.Google Scholar
Jenkins, A. Doake, C.S.M.. 1991 Ice–ocean interaction on Ronne Ice Shelf, Antarctica. J. Geophys. Res., 96(C1), 791813.Google Scholar
Kurtz, D.D. Bromwich, D.H.. 1983 Satellite observed behavior of the Terra Nova Bay polynya. J. Geophys. Res., 88(C14), 97179722.Google Scholar
Kurtz, D.D. Brornwich, D.H.. 1985 A recurring, atmospherically forced polynya in Terra Nova Bay. Antarct. Res. Ser. , 43, 177-201.Google Scholar
Lewis, E.L. Perkin, R.G. 1986 Ice pumps and their rates. J. Geophys. Res., 91(C10), 11, 75611,762.Google Scholar
Lucchitta, B.K. Ferguson, H.M. 1986 Antarctica: measuring glacier velocity from satellite images. Science, 234(4780), 11051108.Google Scholar
MacDonald, T.R. Ferrigno, J.G. Williams, R.S. Lucchitta, B.K.. 1989 Velocity of Antarctic outlet glaciers determined from sequential Landsat images. Antarct. J. U. S., 24(5), 105106.Google Scholar
McIntyre, N.F. 1985 The dynamics of ice–sheet outlets. J. Glacial., 31(108), 99107.Google Scholar
Meneghel, M. Smiraglia, C.. 1991 Preliminary data on the mass balance of the Strandline Glacier (Terra Nova Bay, Antarctica). Mem. Soc. Geol. Ital., 46, 5967.Google Scholar
Orheim, O. Lucchitta, B.K.. 1987 Snow and ice studies by Thematic Mapper and multispectral scanner Landsat images. Ann. Glaciol., 9, 109118.Google Scholar
Orombelli, G. 1990 Holocene environmental changes at Terra Nova Bay (Victoria Land, Antarctica). Mem. Soc. Geol. Ital., 43, 1988 145147.Google Scholar
Orombelli, G. 1991 Glaciers and glacial morphology at Terra Nova Bay: an opportunity for significant studies on environmental and climatic global changes. Mem. Soc. Geol. Ital., 46, 916.Google Scholar
Priestley, R.E. 1923 British (Terra Nova) Antarctic Expedition 1910–13. Physiography (Robertson Bay and Terra Nova Bay regions). London, Harrison and Sons.Google Scholar
Robin, G.de.Q. 1979 Formation, flow, and disintegration of ice shelves. J. Glacial., 24(90), 259271.Google Scholar
Souchez, R. and 8 others. 1991 Ice composition evidence of marine ice transfer along the bottom of a small Antarctic ice shelf. Geophys. Res. Lett., 18(5), 849852.Google Scholar
Steed, R.H.N. Drewry, D.J.. 1982 Radio–echo sounding investigations of Wilkes Land, Antarctica. In Craddock, C., ed. Antarctic geoscience. Madison, WI, University of Wisconsin Press, 969975.Google Scholar
Swithinbank, C. 1988 Satellite image atlas of glaciers of the world. Antarctica. U.S. Geol. Surv. Prof Pap. 1386–B. Google Scholar
Swithinbank, C. Lucchitta, B.K.. 1986 Multi–spectral digital image mapping of Antarctic ice features. Ann. Glaciol.,8, 159163.Google Scholar
Williams, R.S. Ferrigno, Jr,J.G. Kent, T.M. Schoonmaker, J.W. 1982 Landsat images and mosaics of Antarctica for mapping and glaciological studies. Ann. Glaciol., 3, 321326.Google Scholar
Zanon, G. 1989 Ricerche preliminari sul bilancio glaciale nell’ area della Baia Terra Nova (Antartide). Geogr. Fis. Din. Quat., 11(1), 1988 5658.Google Scholar
Figure 0

Fig. 1. Sketch map of Terra Nova Bay and Wood Bay area redrawn on the basis of U.S.G.S topographie maps of Antarctica Reconnaissance Series. Legend: 1: Floating ice shelves, ice tongues and glacier tongues; 2: Fast and bay ice; 3: Ice-free area.

Figure 1

Fig. 2. Subscene of mosaic of SPOT 1 XS images (Borfecchia and Frezzotti, 1991) in false color (RGB:3, 2, 1) showing the Wood Bay area. Legend: 1: Ice front in 1989 (SPOT 1 XS); 2: Ice front in 1972 (Landsat 1 MSS); 3: Ice front in 1963 (U.S.G.S. maps); 4: Radio-echo sounding in meters (Engelhart and others, 1989).

Figure 2

Table I. Surfiàal parameters and ice discharge

Figure 3

Fig. 3. Mosaic of Landsat 4 TM images (62/113 and 62/114 of 17 January 1990) in false color (RGB: 4, 3, 2) showing the Terra Nova Bay area between Nansen Ice Sheet and Clarke Glacier. Legend: 1: Ice front in 1988 (Landsat 4 TM); 2: Ice front in 1973 (Landsat 1 MSS); 3: Ice front in 1960 (U.S.G.S. maps); 4: Radio-echo sounding in meters (Scott Polar Research Institute, in Swithinbank, 1988).

Figure 4

Fig. 4. Velocity, width and thickness of David Glacier-Drygalski Ice Tongue.

Figure 5

Fig. 5. Schemetic representation of David Glacier-Drygalski Ice Tongue. Legend: 1: Ice derived from snowfall on the floating glacier and ice tongue; 2: Sea ice that freezes to the base of the footing glacier and ice tongue; 3: Sea ice; 4: Flow rale; 5: Basal melting; 6: Basal freezing; 7: Ice discharge; 8: Ablation induced by katabatic winds; 9: Snow accumulation; 10: Katabatic winds.

Figure 6

Fig. 6. Subscene of SPOT 1 XS image (27/547, 19 December 1988) in false color (RGB: 3, 2, 1) showing Hells Gate. Legend: 1: Ice front in 1988 (SPOT 1 XS); 2: Ice front in 1985 (TMA 2851); 3: Ice front in 1956–57 (TMA 325 and 365); 4: Flow rate.