Hostname: page-component-cd9895bd7-lnqnp Total loading time: 0 Render date: 2024-12-22T15:05:56.587Z Has data issue: false hasContentIssue false

Measurements of the Radiation Temperature of Antarctic Icebergs and the Surrounding Surface Water*

Published online by Cambridge University Press:  20 January 2017

A. Foldvik
Affiliation:
Geofysisk Institutt, Universitetet i Bergen, 5014 Bergen, Norway
T. Gammelsrød
Affiliation:
Geofysisk Institutt, Universitetet i Bergen, 5014 Bergen, Norway
Y. Gjessing
Affiliation:
Geofysisk Institutt, Universitetet i Bergen, 5014 Bergen, Norway
Rights & Permissions [Opens in a new window]

Abstract

During the Norwegian Antarctic Research Expedition 1978–79, temperature measurements of a number of icebergs and the surrounding surface water were made, using an airborne precision radiation thermometer. All icebergs were embedded in cold water-masses with temperatures generally below 0°C and thus the observed temperature anomalies were relatively small, ΔT ≈ 1 deg. Examples of the influence of icebergs on the sea surface temperature including a possible example of upwelling will be shown. The temperature of the snow-covered iceberg surface was almost constant with individual variations ΔT ≈ 0.2 deg. Local minima indicative of snow-covered crevasses were observed.

Type
Research Article
Copyright
Copyright © International Glaciological Society 1980

Introduction

The object of the study, which was carried out during the Norwegian Antarctic Research Expedition 1978–79, was to detect surface-temperature anomalies due to the presence of floating icebergs. In the present note the term surface temperature will be used in the sense of bulk surface temperature which is the temperature of the upper tens of centimetres as obtained from a bucket sample. This surface temperature should be distinguished from the skin surface temperature which is measured remotely by radiation techniques.

In temperate and high latitudes the vertical heat flux from the sea surface to the atmosphere is usually positive. Immediately below the air-sea interface the transfer of heat (and momentum) is mainly effected by molecular processes and the vertical temperature gradient is constant and relatively large.

Below this thin viscous sub-layer the vertical transfer is mainly due to turbulent mixing and the temperature gradient is small. The result is that the upper few millimetres of the surface water are typically a few tenths of a degree Celsius cooler than the water below, as demonstrated by Reference WoodcockWoodcock (1941). With radiometric techniques it is possible to investigate in detail the temperature of the surface itself, i.e. the skin temperature, following on the earlier work of Reference BallBall (1954), Reference Ewing and McAlisterEwing and McAlister (1960), Reference McAlisterMcAlister (1964), and Reference McAlister and McLeishMcAlister and McLeish (1969). The thin viscous sub-layer giving rise to the difference between bulk temperature and skin temperature undergoes rapid changes due to the presence of convection, wind, waves, etc. The radiation signal therefore exhibits large fluctuations, as, for example, shown by Reference Simpson and PaulsonSimpson and Paulson (1980). The task of revealing bulk surface temperature signals from observations of radiation temperatures is further complicated by the fact that this bulk surface temperature signal is presumably weak. This is due to the near-freezing temperatures of the water mass in which the icebergs are embedded.

Detection of Surface Temperature Anomalies

In the area of investigation the upper few hundred metres of the water column was almost homogeneous with temperatures below −1.5°C and with a warmer (≈0°C) but variable top layer. For this reason we expected rather small temperature anomalies due to the presence of an iceberg. The task of locating small surface-temperature anomalies using a precision radiation thermometer is not straightforward (Reference SaundersSaunders 1967). The radiation thermometer measures the skin temperature of the surface which may differ considerably from the bulk surface temperature. For example, a net heat loss from the surface due to long-wave radiation, conduction, and evaporation gives rise to a thin (<1 mm) layer of cold saline water which may become unstable and convect downwards in quasistationary sheets as seen in the experiments of Reference Spangenberg and RowlandSpangenberg and Rowland (1961). Conversely, a net heat gain to the surface may produce a thin stable layer of warmer water. If the external conditions giving rise to the skin-temperature anomaly were horizontally homogeneous one might expect that the skin temperature exhibited a constant off-set from the surface temperature. However, mixing due to wind will reduce the difference between surface temperature and skin temperature and since the iceberg influences the local wind field we may expect corresponding horizontal variations in skin temperature. Such wind-induced horizontal variations in the skin temperature may be erroneously interpreted as real horizontal variations in surface bulk temperature. Also, they may mask existing small anomalies in the surface temperature.

On a smaller scale inhomogeneities are also due to drifting sea ice in the presence of wind. Under freezing conditions there is a tendency for ice crystals to form behind isolated chunks of ice, often forming a line of ice crystals downwind. The radiation temperature from such areas may be considerably lower than in the neighbouring open water.

Instrumentation

The measurements were made using the precision radiation thermometer PRT-5 manufactured by Barnes Engineering Co., Connecticut, U.S.A. This instrument measures radiation in the 8–14 µm region. The field of view is 2° and the response time 50 ms. The instrument was provided with a 15 cm-long insulated tube to prevent unwanted ventilation of the sensor and was then mounted under a Bell Jetranger helicopter with the tube axis vertically. The recordings were made on a paper-strip chart recorder. The temperature variations in the area of observations were small, typically below 2deg, and the sensitivity was therefore increased by feeding the signal into a bridge circuit. The instrument was calibrated before and after each flight for the ice-water zero point, taking the necessary precautions to obtain stable readings. The internal reference point was recorded at intervals during the flight. Corrections due to absorption by carbon dioxide in the air column have been neglected due to the low flight level and the low air temperatures (Reference SaundersSaunders 1970). The spatial resolution ΔX depends on the speed of the vehicle V, the observation height h, and the response time Δt, of the instrument or the recorder (whichever is highest). Denoting the field of view with α(rad) the spatial resolution is ΔXαh provided V<αh/Δt. At higher speeds the resolution approaches VΔt. With typical values: h = 30 m, Δt = 0.5 s, α = 3.5 × 10−2 rad we obtain ΔX ≈ 1 m when V < 20 m s−1. If we wish to retain this spatial resolution on the paper-strip chart (where ΔX p ≈ 1 mm) then the paper speed needed is where V p where . On longer flights we have used a paper speed of 0.13 cm s−1 which gives a spatial resolution better than 10 m at speeds 10 m s−1.

Observations

Two examples will be discussed, (i) Iceberg no.7. This icebcrg was visited on 4 February 1979 at 11 00 GMT. There was partial cloud and a light breeze, and the upper sea-surface layer had warmed slightly. The surface temperature (bucket) was −0.1°C. The PRT-5 was flown as indicated in Figure 1, and the actual record is shown in Figure 2. Lower temperatures were recorded in the vicinity of the berg and there was a zone of distinctly colder water on the windward (eastern) side. The observed radiation temperatures were lower than the observed bucket temperature. We may try to explain the broad windward temperature minimum solely as a minimum in skin temperature. This would probably require the existence of a minimum in the wind-field on the windward side of the berg which is not very likely (Fig. 1). We therefore conclude that the observed minima in radiation temperature on the windward side of the iceberg correspond to minima in surface temperature due to the presence of the iceberg and, except for a small negative off-set, Figure 1 is interpreted as giving surface temperatures.

Fig. 1. Isotherms and track lines, iceberg no. 7.

Fig. 2. PRT-5 record, iceberg no. 7. The letters refer to Figure 1.

The broad windward temperature minimum is interpreted as the result of turbulent mixing of colder sub-surface water with the warmer surface water in a wake. The narrow, very cold zone on the windward side probably was the result of upwellig of cold water produced by cooling (and a little melting) at the vertical side of the berg. Figure 1 gives the impression of an iceberg in clockwise rotation. This is a plausible interpretation since we know from observations that icebergs may rotate. However, it should be kept in mind that the isotherms shown in Figure 1 have been drawn on the basis of observations along two lines only and other solutions are therefore quite possible.

The observed surface temperatures of the snow-covered iceberg were close to zero and there was a small horizontal gradient with temperatures increasing downwind. This may be attributed to the reduced wind-speed downwind due to the build-up of the frictional layer with increasing distance from the edge. The record from the iceberg surface also showed some fine structure with temperature anomalies of ≈ 0.1°C. These horizontal inhomogeneities may have been due to crevasses covered by a thin layer of snow.

(ii) Iceberg no.15. This iceberg was visited on 22 February 1979 at 15 00 GMT. The weather was overcast with a light breeze from E.N.E. The PRT-5 flight tracks are shown schematically in Figure 3 and the general hydrographic situation is demonstrated by the conductivity-temperature-depth (CTD) station in Figure 4. In Figure 5 is shown the PRT-5 records obtained during two flights at the distance of 30 and 100 m from the berg. The records show on the average lower temperatures for the track 30 m from the berg. This was at least partly due to a thin layer of ice needles forming a band of grease ice of varying width as indicated in Figure 3. A comparison of the tracks does not reveal significant temperature differences outside the grease-ice areas. The temperature fluctuations outside the ice areas were typically ± 0.2 deg whereas the presence of ice in this case produced temperature excursions of about 1 deg. It should be noted that the temperature differences measured between partly ice-covered and open-water areas depend largely on the properties of the ice cover and on the radiation balance.

Fig. 3. Track lines, iceberg no.15.

Fig. 4. CTD no. 42, iceberg no.15. Temperature versus depth.

Fig. 5. PRT-5 record, 30 and 100 m from iceberg no.15. The letters refer to Figure 3.

The records obtained from the flights across the iceberg are shown in Figure 6. The radiation temperature of the berg surface was in the range −6 to −7°C with typical fluctuations within ± 0.15 deg. These fluctuations were associated with horizontal scales of 50 to 100 m but there were also smaller oscillations on the 10 m scale. There were a few larger anomalies where the temperature dropped about 0.5 deg below the average. In the A-F section of Figure 6 there may be seen three such distinct features about 1 000 m apart. These may have been due to bands of crevasses in which the temperature was below the surface value.

Fig. 6. PRT-5 record, across iceberg no.15. The letters refer to Figure 3.

Conclusion

Airborne radiometers represent powerful tools for the study of temperature anomalies of the sea surface and snow-covered surfaces in high-latitude regions. High-resolution relative values are easily obtained which yield information about the local dynamics of the water influenced by drifting icebergs and about crevasses etc. in the snow-ice surface. Reliable absolute values require careful calibrations at regular intervals combined with good surface observations.

Footnotes

page 19 note *

Publication No.23 of the Norwegian Antarctic Research Expeditions (1978–79)

References

Ball, F K 1954 Sea surface temperatures. Australian Journal of Physics 7(4): 649652 Google Scholar
Ewing, G, McAlister, E D 1960 On the thermal boundary layer of the ocean. Science 131(3410): 13741376 Google Scholar
McAlister, E D 1964 Infrared optical techniques applied to oceanography. 1. Measurement of total heat flow from the sea surface. Applied Optics 3(5): 609612 Google Scholar
McAlister, E D, McLeish, W 1969 Heat transfer in the top millimeter of the ocean. Journal of Geophysical Research 74(13) : 34083413 Google Scholar
Saunders, P M 1967 Aerial measurements of sea surface temperature in the infrared. Journal of Geophysical Research 72(16) : 41094117 Google Scholar
Saunders, P M 1970 Corrections for airborne radiation thermometry. Journal of Geophysical Research 75(36): 75967601 Google Scholar
Simpson, J J, Paulson, C A 1980 Small-scale sea surface temperature structure. Journal of Physical Oceanography 10(3): 399410 2.0.CO;2>CrossRefGoogle Scholar
Spangenberg, W G, Rowland, W R 1961 Convective circulation in water induced by evaporative cooling. Physics of Fluids 4(6) : 743750 Google Scholar
Woodcock, A H 1941 Surface cooling and streaming in shallow fresh and salt waters. Journal of Marine Research 4(2) : 153161 Google Scholar
Figure 0

Fig. 1. Isotherms and track lines, iceberg no. 7.

Figure 1

Fig. 2. PRT-5 record, iceberg no. 7. The letters refer to Figure 1.

Figure 2

Fig. 3. Track lines, iceberg no.15.

Figure 3

Fig. 4. CTD no. 42, iceberg no.15. Temperature versus depth.

Figure 4

Fig. 5. PRT-5 record, 30 and 100 m from iceberg no.15. The letters refer to Figure 3.

Figure 5

Fig. 6. PRT-5 record, across iceberg no.15. The letters refer to Figure 3.