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3 - Temperature

Published online by Cambridge University Press:  05 July 2014

Ian Strangeways
Affiliation:
TerraData
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Summary

This strange severity of the weather made me very desirous to know what degree of cold there might be in such an exalted and near situation as Newton. We had, therefore, on the morning of the 10th (December 1784), written to Mr —, and entreated him to hang out his thermometer, made by Adams, and to pay some attention to it morning and evening, expecting wonderful phenomena, in so elevated a region, at two hundred feet or more above my house. But, behold! On the 10th, at eleven at night, it was down only to 17°(F) and the next morning at 22°, when mine was at 10°! We were so disturbed at this unexpected reverse of comparative local cold, that we sent one of my glasses up, thinking that of Mr — must, somehow, be wrongly constructed. But, when the instruments came to be confronted, they were exactly together; so that for one night at least, the cold at Newton was 18° (—7.8 °C) less than at Selborne, and, through the whole frost, 10° or 12°.

Gilbert White. The Natural History of Selborne (Severe frosts).

The variable

Only about 17% of solar radiation is absorbed directly by the atmosphere as it passes through it (Lockwood 1974). In fact the atmosphere is heated primarily as follows: solar radiation heats the ground and the ground’s heat is transferred to the air, firstly by molecular diffusion across the laminar boundary layer (a layer only a millimetre or so thick, which clings to most surfaces); beyond this, in the turbulent boundary layer, transfer is by turbulence, which is much more effective at transferring heat than is diffusion. Heat is also, thereafter, transferred by convection, bubbles of warmer air rising into the cooler air above. This transfer of warmed air away from the surface is the sensible heat flux. While it is difficult to measure the rate of energy transfer (see The eddy correlation method; Chapter 7), the resultant changes in air temperature are important and more easily measured.

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Chapter
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Publisher: Cambridge University Press
Print publication year: 2003

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References

Bryant, D. (1968) An investigation into the response of thermometer screens – the effect of wind speed on the lag time. Met. Mag. 97, 183–6, 256.
Gilman, K. (1977) Movement of heat in soils. Institute of Hydrology Report No. 44.Google Scholar
Huband, N. D. S. (1990) Temperature and humidity measurements on automatic weather stations. A comparison of radiation shields. Internal report, Campbell Scientific Ltd.Google Scholar
Keil, M. (1996) Temperature measurements in a Stevenson screen. University of Reading, Dept of Meteorology report.Google Scholar
Langlo, K. (1949) The effects of the solar eclipse of July 1945 on the air temperature and an examination of the lag of the thermometer exposed in a screen. Met. Ann. Oslo, 3, No. 3, 59–74.Google Scholar
Lockwood, G. L. (1974) World Climatology, An Environmental Approach. Edward Arnold, London. ISBN 0 7131 5701 1.Google Scholar
McTaggart-Cowan, J. D. & McKay, D. J. (1976) Radiation shields – an intercomparison. Canadian Atmospheric Environment Service unpublished report.Google Scholar
Painter, H. E. (1977) An analysis of the differences between dry-bulb temperatures obtained from an aspirated psychrometer and those from a naturally ventilated large thermometer screen at Kew Observatory. Meteorological Office, UK, unpublished report. Copy available in National Meteorological Library, Bracknell, UK.Google Scholar
Strangeways, I. C. (1999) Back to basics: the ‘met enclosure’: Part 4 – temperature. Weather, 54, pp. 262–9.CrossRefGoogle Scholar

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  • Temperature
  • Ian Strangeways, TerraData
  • Book: Measuring the Natural Environment
  • Online publication: 05 July 2014
  • Chapter DOI: https://doi.org/10.1017/CBO9781139087254.003
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  • Temperature
  • Ian Strangeways, TerraData
  • Book: Measuring the Natural Environment
  • Online publication: 05 July 2014
  • Chapter DOI: https://doi.org/10.1017/CBO9781139087254.003
Available formats
×

Save book to Google Drive

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Google Drive.

  • Temperature
  • Ian Strangeways, TerraData
  • Book: Measuring the Natural Environment
  • Online publication: 05 July 2014
  • Chapter DOI: https://doi.org/10.1017/CBO9781139087254.003
Available formats
×