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Hudson's Bay Company ship's logbooks: a source of far North Atlantic weather data

Published online by Cambridge University Press:  06 May 2011

Catharine Ward  and
Dennis Wheeler
Catharine Ward
Affiliation:
Faculty of Applied Sciences, University of Sunderland, Sunderland SR1 3PZ (denniswheeler1948@msn.com)
Dennis Wheeler
Affiliation:
Faculty of Applied Sciences, University of Sunderland, Sunderland SR1 3PZ (denniswheeler1948@msn.com)
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Abstract

The Arctic region is widely recognised to be one of the most sensitive to climate change. Here, the consequences of current trends will be felt most keenly; ice cap melting and thinning and the consequent implications for sea level rise and loss of habitat may be profound. Yet these regions remain amongst the most poorly chronicled. Recent advances in satellite monitoring and instrumental observations now provide valuable information, but this record extends over little more than half a century. For earlier times, the record is, at best, patchy and inconsistent. This is not, however, to imply that all such data and information have been recognised and fully exploited. This is far from the case and this paper draws attention to largely overlooked documentary sources that can extend our knowledge of the far North Atlantic climate back to the late eighteenth century. These documents consist of the logbooks of sailing ships navigating those hazardous waters in the late eighteenth and early- to mid-nineteenth centuries.

This paper focuses specifically on those logbooks kept on board Hudson's Bay Company (HBC) ships on their regular annual voyages between the UK and Hudson's Bay between 1760 and 1870. The information they contain is shown to be detailed, reliable and of unique character for the period and place. The style and form of presentation of the logbooks is reviewed and particularly those aspects that deal with the daily meteorological information they contain. Attention is also drawn to the high degree of homogeneity found in the logbooks in terms of presentation and methods of preparation, rendering them directly and helpfully comparable one with another. A specific example is offered of the benefits of using these data and it is proposed that this set of logbooks, when taken collectively and, embracing as it does over a century from 1750 provides a matchless, substantial and uniformly reliable source of oceanic weather information for the far North Atlantic for what can be regarded as the ‘pre-instrumental’ period (before 1850).

Type
Research Article
Information
Polar Record , Volume 48 , Issue 2 , April 2012 , pp. 165 - 176
Copyright
Copyright © Cambridge University Press 2011

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References

Alt, B.T. 1978. Synoptic climate controls of mass-balance variations on Devon Island ice cap. Arctic and Alpine Research 10: 6180.CrossRefGoogle Scholar
Alt, B.T. 1979. Investigation of summer synoptic climate conditions on the mass balance of Meighen ice cap. Atmosphere-Ocean 17: 181199.CrossRefGoogle Scholar
Ball, T.F. 1983. Preliminary analysis of early instrumental temperature records from York Factory and Churchill Factory. Syllogeu s 49: 203219.Google Scholar
Ball, T.F. 1992. Historical and instrumental evidence of climate: western Hudson Bay, Canada 1714 –1850. In: Bradley, R.S., and Jones, P.D. (editors). Climate since AD 1500. London: Routledge: 4073.Google Scholar
Bloxham, J., and Gubbins, D.. 1985. The secular variation of the Earth's magnetic field. Nature 317: 777781.CrossRefGoogle Scholar
Brázdil, R., Pfister, C., Wanner, H., von Storch, H., and Luterbacher, J.. 2005. Historical climatology in Europe – the state of the art. Climatic Change 70: 363430.CrossRefGoogle Scholar
Cappellen, J., Laursen, E.V., Jørgensen, B.V., and Kern-Hansen, C.. 2007. DMI monthly climate data collection 1768–2006, Denmark, Faroe Islands and Greenland. Copenhagen: Danish Meteorological Institute (Technical report 07-06): 53.Google Scholar
Catchpole, A. J.W. 1992. Hudson's Bay Company ships’ logbooks as sources of sea ice data, (1751–1870). In: Bradley, R.S., and Jones, P. D. (editors). Climate since AD 1500. London: Routledge: 1739.Google Scholar
Catchpole, A.J.W., and Ball, T.F.. 1981. Analysis of historical evidence of climatic change in western and northern Canada. Syllogeus 33: 4896.Google Scholar
Catchpole, A.J.W., and Faurer, M.A.. 1983 Summer sea ice severity in Hudson Strait, 1751–1870.Climatic Change 5: 115139.CrossRefGoogle Scholar
Catchpole, A.J.W., and Faurer, M.A.. 1985. Ships’ logbooks, sea ice and the cold summer of 1816 in Hudson Bay and its approaches. Arctic 38: 121128.CrossRefGoogle Scholar
Catchpole, A.J.W., and Hanuta, I.. 1989. Severe summer ice in Hudson strait and Hudson Bay following major volcanic eruptions, 1751 to 1889 A.D. Climatic Change 14: 6179.CrossRefGoogle Scholar
Catchpole, A.J.W., and Moodie, D.W.. 1976. Valid climatological data from historical sources by content analysis. Science 193: 5153.Google Scholar
Chappell, E. 1818. Voyage of His Majesty's ship ‘Rosamond’ to Newfoundland and the southern coast of Labrador: of which countries no account has been published by any British traveller since the reign of Queen Elizabeth. London: J. Mawman.Google Scholar
Davis, J. 1594. The seamans’ secrets. London: Thomas Dawson.Google Scholar
Demarée, G.R., and Ogilvie, A.E.J.. 2001. Bons Baisers d'Islande: climatic environmental and human dimensions impacts of the Lakagígar eruption (1783–1784) in Iceland. In: Jones, P.D., Ogilvy, A.E.G., Davies, T.D., and Briffa, K.R. (editors). History and climate: memories of the future? New York: Kluwer Academic: 219246.CrossRefGoogle Scholar
Dunbar, M. 1971 Increasing severity of ice conditions in Baffin Bay and Davis Strait and its effect on the extreme limits of ice. In: Karlson, T. (editor). Sea ice. Reykjavik: National Research Council of Iceland (Proceedings of International Conference, Reykjavik, 1971): 8793.Google Scholar
Falconer, W. 1780. Dictionary of the marine. London: Murray.Google Scholar
Fuson, R.H. 1987. The log of Christopher Columbus. Southampton: Ashford Press.Google Scholar
Garcia-Herrera, R., Können, G.P., Wheeler, D., Prieto, M.R., Jones, P.D., and Koek, F.B.. 2005b. CLIWOC: A climatological database for the world's oceans 1750–1854. Climatic Change 73: 112.CrossRefGoogle Scholar
Garcia Herrera, R., Können, G.P., Wheeler, D., Prieto, M.R., Jones, P.D., and Koek, F.B.,. 2006. CLIWOC multilingual meteorological dictionary. De Bilt, The Netherlands: Royal Dutch Meteorological Institute (KNMI).Google Scholar
García-Herrera, R., Wilkinson, C., Koek, F.B., Prieto, M.R., Calvo, N., and Hernández, E., 2005a. Description and general background to ships’ logbooks as a source of climatic data. Climatic Change, 73: 1336.CrossRefGoogle Scholar
Great Britain, Admiralty. 1731. Naval instructions. London.Google Scholar
HBC (Hudson's Bay Company). 1750–1838, 1842–1870. Logbooks. Winnipeg; Archives of Manitoba Hudson's Bay Company archives. URL: http://www.gov.mb.ca/chc/archives/hbca/ (copies in The National Archives, Kew, London BH1/1509–1639).Google Scholar
HBC (Hudson's Bay Company). 1783. Logbook of Prince Rupert. Winnipeg; Archives of Manitoba Hudson's Bay Company archives. URL: http://www.gov.mb.ca/chc/archives/hbca/ (copy in The National Archives, Kew, London BH1/1603).Google Scholar
Harries, H. 1928. Nautical time. The Mariner's Mirror 1928: 364370.CrossRefGoogle Scholar
Hewson, J.B. 1951. A history of the practice of navigation. Glasgow: Brown, Son and Ferguson.Google Scholar
Hopper, J.F. 1985. Early meteorological observations at Fort Enterprise, Northwest Territories, Canada. Polar Record 22: 684688.CrossRefGoogle Scholar
Jones, P.D., and Salmon, M.. 2005. Preliminary reconstructions of the North Atlantic oscillation and the southern oscillation index from measures of wind strength and direction taken during the CLIWOC period. Climatic Change 73: 131154.CrossRefGoogle Scholar
Kay, P.A. 1995. An early nineteenth century meteorological register from the eastern Canadian Arctic. Polar Record 31: 335342.CrossRefGoogle Scholar
Kington, J. 1988. The weather of the 1780s over Europe. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
Klimenko, V.V., and Astrina, N.A.. 2006. Documentary evidence of strong climate fluctuations of the Russian Arctic in the XV–XXth centuries. History and Modernity 1: 179217.Google Scholar
Lamb, H.H. 1982; Climate, history and the modern world. London: Methuen.Google Scholar
Lavery, B. 1989. Nelson's navy: the ships, men and organisation 1793–1815. London: Conway Maritime Press.Google Scholar
Lüdecke, C. 2005. East meets west: meteorological observations of the Moravians in Greenland and Labrador since the 18th century. History of Meteorology 2: 123132.Google Scholar
Maury, M.F. 1854. Explanations and sailing directions to accompany the wind and current charts. Philadelphia: Biddle.Google Scholar
Meteorological Office. 1948. International meteorological code. Decode for use of shipping, incorporating the codes for weather reports from and to ships and the analysis code for use of shipping. London: Meteorological Office.Google Scholar
Meteorological Office. 1977. Marine observer's handbook. London: HMSO.Google Scholar
Newell, J. 1983. Preliminary analysis of sea-ice conditions in the Labrador Sea during the nineteenth century. Syllogeus 49: 108129.Google Scholar
Norrie, J.W. 1889. A complete epitome of practical navigation (‘new’ edition). London: Norrie and Wilson.Google Scholar
Ogilvie, A.E.J. 1984. The past climate and sea-ice record from Iceland, part 1: data to1780. Climatic Change 6: 131152.CrossRefGoogle Scholar
Przybylak, R. 2000. Air temperature in the Canadian Arctic in the mid-nineteenth century based on data from expeditions. Prace Geograficzne 107: 251258.Google Scholar
Przybylak, R. 2004. Temperatura powietrza w Arktyce w okresie Pierwszego Międzynarodowego Roku Polarnego 1882/83 [Air temperature in the Arctic in the period of first International Polar Year 1882/83]. Polish Polar Studies, XXX. Miedzynarodowe Sympozjum Polarne, Gdynia; 307320 [in Polish].Google Scholar
Przybylak, R., and Vizi, Z.. 2005. Air temperature changes in the Canadian Arctic from the early instrumental period to modern times. International Journal of Climatology 25: 15071522, DOI: 10.1002/joc.1213.CrossRefGoogle Scholar
Przybylak, R., Vizi, Z., and Wyszy'nski, P.. 2010. Air temperature changes in the Arctic from 1801 to 1920. International Journal of Climatology 30: 791812.CrossRefGoogle Scholar
Robertson, J. 1786. The elements of navigation. London: Nourse.Google Scholar
Sobel, D. 1996. Longitude. London: Fourth Estate.Google Scholar
Speerschneider, C.I.H. 1931. The state of ice in the Davis Strait, 1820–1930. Copenhagen: Danish Meteorological Institute, (Publikationer fra det Danske Meteorologiske Institut 8).Google Scholar
Taylor, E.G.R. 1956. The haven-finding art: a history of navigation from Odysseus to Captain Cook. London: Hollis and Carter.Google Scholar
Vinther, B.M., Andersen, K.K., Jones, P.D., Briffa, K.R., and Cappellen, J.. 2006. Extending Greenland temperature records into the late eighteenth century. Journal of Geophysical Research 111: D11105; 113.CrossRefGoogle Scholar
Ward, C., and Dowdeswell, J.A.. 2006. On the meteorological instruments and observations made during the 19th century exploration of the Canadian Northwest Passage. Arctic, Antarctic and Alpine Research 38: 454464.CrossRefGoogle Scholar
Wheeler, D. 2005. An examination of the accuracy and consistency of ships’ logbook weather observations and records. Climatic Change 73: 97116.CrossRefGoogle Scholar
Wheeler, D., and Garcia-Herrera, R.. 2009. Ships’ logbooks in climatological research: reflections and prospects. Annals of the New York Academy of Science 1146: 115 (Trends and directions in climate research).CrossRefGoogle Scholar
Wheeler, D., and Wilkinson, C.. 2004. From calm to storm: the origins of the Beaufort wind scale. The Mariner's Mirror 90: 187201.CrossRefGoogle Scholar
Wheeler, D., and Wilkinson, C.. 2005. The determination of logbook wind force and weather terms: the English case. Climatic Change 73: 160185.CrossRefGoogle Scholar
Williams, G. 1983. The Hudson's Bay Company and the fur trade 1670–1870 Beaver 63: 482, 8590.Google Scholar
Wilson, C. 1982. The summer season along the east coast of Hudson Bay during the nineteenth century. Part 1. General introduction; climatic controls, calibration of the instrumental temperature data 1814 to 1821. In: Canadian Climate Centre Report 82–4: 1–223.Google Scholar
Wilson, C. 1983a. Some aspects of calibration of early Canadian temperature records in the Hudson's Bay Company Archives: a case study for the summer season, eastern Hudson/James Bay, 1814 to 1821. Syllogeus 49: 144202.Google Scholar
Wilson, C. 1983b. The summer season along the east coast of Hudson Bay; summers at Great Whale, Fort George, Eastmain, 1814–1821. In: Canadian Climate Centre Report 83-9: 1–145.Google Scholar
Wilson, C. 1985 The Little Ice Age on eastern Hudson/James Bay: the summer weather and climate at Great Whale, Fort George and Eastmain, 1814–1821, as derived from the Hudson's Bay Company records. Syllogeus 55: 147190.Google Scholar
Wilson, C. 1988. The summer season along the east coast of Hudson Bay during the nineteenth century. Part III. Summer thermal and wetness indices. B. The indices 1800 to 1900. In: Canadian Climate Centre Report 88–3: 1–42.Google Scholar
Wilson, C. 1992. Climate in Canada, 1809–20: three approaches to the Hudson's Bay Company archives as an historical database. In: Harington, C.R. (editor). The year without a summer? World climate in 1816. Ottawa: Canadian Museum of Nature: 162184.Google Scholar
Wood, K., and Overland, J.E.. 2003. Accounts from 19th-century Canadian Arctic explorers’ logs reflect present climate conditions. EOS 84: 410 and 412.Google Scholar
Wood, K., and Overland, J.E.. 2006. Climate lessons from the first International Polar Year. Bulletin of the American Meteorological Society 87: 16851697.CrossRefGoogle Scholar
World Meteorological Organisation. undated. WMO sea-ice nomenclature. Geneva: World Meteorological Organisation (report 259 supplement 5).Google Scholar