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Land use and a low-carbon society

Published online by Cambridge University Press:  22 April 2013

Colin D. Campbell ,
Allan Lilly ,
Willie Towers ,
Stephen J. Chapman ,
Alan Werritty  and
Nick Hanley
Colin D. Campbell
Affiliation:
The James Hutton Institute, Craigiebuckler, Aberdeen, AB15 8QH, UK Department of Soil and Environment, Swedish University of Agricultural Sciences, Box 7014, SE-750 07, Uppsala, Sweden
Allan Lilly
Affiliation:
The James Hutton Institute, Craigiebuckler, Aberdeen, AB15 8QH, UK
Willie Towers
Affiliation:
The James Hutton Institute, Craigiebuckler, Aberdeen, AB15 8QH, UK
Stephen J. Chapman
Affiliation:
The James Hutton Institute, Craigiebuckler, Aberdeen, AB15 8QH, UK
Alan Werritty
Affiliation:
UNESCO, Centre for Water Law, Policy and Science, University of Dundee, Dundee, DD1 4HN, UK
Nick Hanley
Affiliation:
Economics Division, School of Management, University of Stirling, Stirling, FK9 4LA, UK
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Abstract

Land use and the management of our natural resources such as soils and water offer great opportunities to sequester carbon and mitigate the effects of climate change. Actions on forestry, soil carbon and damaged peatlands each have the potential to reduce Scottish emissions in 2020 by hundreds of thousands of tonnes. Most actions to reduce emissions from land use have beneficial effects on other ecosystem services, so if we can cut emissions we can in many circumstances improve the environment. The cost of reducing emissions through land use change can be low in relation to other means of cutting emissions. The Scottish Land Use Strategy and the Ecosystem Approach it calls for, employing the concept of ecosystem services, offers a way of balancing environmental, social and economic demands on the land. Scotland's land, soils, forests and waters are all likely to be significantly altered by future climate change. Each of these components of the land-based environment offers opportunities for mitigation and adaptation to climate change. The emerging new imperatives for securing food, water and energy at a global level are equally important for Scotland, and interact with the need for environmental security and for dealing with climate change.

Keywords

adaptationcarbon sequestrationclimate changeecosystem servicesecosystem approachforestrygreenhouse gas emissionsmitigationsoilwater
Type
Articles
Information
Earth and Environmental Science Transactions of The Royal Society of Edinburgh , Volume 103 , Issue 2: Facing up to Climate Change , July 2012 , pp. 165 - 173
Copyright
Copyright © The Royal Society of Edinburgh 2012 

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References

5. References

Artz, R., Chapman, S., Donnelly, D. & Matthews, R. 2012. Potential Abatement from Peatland Restoration. ClimateXChange enquiry number 1202–02. Edinburgh: ClimateXChange.Google Scholar
Bain, C. G., Bonn, A., Stoneman, R., Chapman, S., Coupar, A., Evans, M., Gearey, B., Howat, M., Joosten, H., Keenleyside, C., Labadz, J., Lindsay, R., Littlewood, N., Lunt, P., Miller, C. J., Moxey, A., Orr, H., Reed, M., Smith, P., Swales, V., Thompson, D. B. A., Thompson, P. S., Van de Noort, R., Wilson, J. D. & Worrall, F. 2011. IUCN UK Commission of Inquiry on Peatlands. Edinburgh, UK: IUCN UK Peatland Programme.Google Scholar
Bibby, J. S., Douglas, H. A., Thomasson, A. J. & Robertson, J. S. 1982. Land Capability Classification for Agriculture. Soil Survey of Scotland Monograph. Aberdeen: Macaulay Institute for Soil Research.Google Scholar
Brown, I., Towers, W., Rivington, M. & Black, H. I. J. 2008. Influence of climate change on agricultural land-use potential: adapting and updating the land capability system for Scotland. Climate Research 37, 4357.Google Scholar
Cannell, M., Milne, R., Hargreaves, K. J., Brown, T. A. W., Cruickshank, M. M., Bradley, R. I., Spencer, T., Hope, D., Billett, M. F., Adger, W. N. & Subak, S. 1999. National inventories of terrestrial carbon sources and sinks: the UK experience. Climatic Change 42, 505–30.Google Scholar
Caparros, A., Cerda, E., Ovando, P. & Campos, P. 2010. Carbon sequestration with reforestation with biodiversity scenic values. Environmental and Resource Economics 45, 4972.Google Scholar
Chapman, S. J. 2010. Carbon sequestration in soils. In Hester, R. E. & Harrison, R. M. (eds) Carbon Capture: Sequestration and Storage. Issues in Environmental Science and Technology 29, 179200. Cambridge, UK: The Royal Society of Chemistry.Google Scholar
Chapman, S. J., Bell, J., Lilly, A. & Donnelly, D. 2009. Carbon stocks in Scottish peatlands. Soil Use and Management 25, 105–12.Google Scholar
DTZ. 2007. Scottish primary food and drink produce processed in Scotland. Edinburgh: DTZ.Google Scholar
Forestry Commission. 2006. Forestry Statistics 2006. http://www.forestry.gov.uk/website/ForestStats2006.nsf/byunique/index_main.html (Accessed 31/04/2012).Google Scholar
Forestry Commission. 2010. Woodland Area, Planting and Restocking. http://www.forestry.gov.uk/pdf/area2010.pdf/$FILE/area2010.pdf; accessed 31/05/2012.Google Scholar
Hanley, N. & Brennan, D. 2012. Economics of a low-carbon future. Earth and Environmental Science Transactions of the Royal Society of Edinburgh 103, 149–56.Google Scholar
General Register Office for Scotland. 2009. Projected Population for Scotland (2008-based).Google Scholar
Haines-Young, R. & Potschin, M. 2007. The Ecosystem Concept and the Identification of Ecosystem Goods and Services in the English Policy Context. Review Paper to Defra. Project Code NR0107. 21pp.Google Scholar
Jackson, J., Li, Y., Murrells, T., Passant, N., Sneddon, S., Thomas, J., Thistlewaite, G., Dyson, K. & Cardenas, L. 2007. Greenhouse Gas Inventories for England, Scotland, Wales and Northern Ireland: 1990–2007. Defra, The Scottish Executive, The Welsh Assembly Government, The Northern Ireland Department of Environment. www.airquality.co.uk/reports/cat07/0909231418_DA_GHGI_report_2007_maintext_Issue_1.pdf Accessed 31/05/2012.Google Scholar
Lilly, A., Ball, B., McTaggart, I., & DeGroote, J. 2009. Spatial modelling of nitrous oxide emissions at the national scale by upscaling using soil, climate and land use information. Global Change Biology 15, 2321–32.Google Scholar
Loh, P. S., Reeves, A., Miller, A .E. J., Harvey, S. M. & Overnell, J. 2010. Sediment fluxes and carbon budgets in Loch Creran, western Scotland. Geological Society, London, Special Publications 344, 103–24.Google Scholar
Mackey, E. C. & Mudge, G. 2010. Scotland's Wildlife: An Assessment of Biodiversity in 2010. Inverness: SNH.Google Scholar
Moran, D., MacLeod, M., Wall, E., Eory, V., Pajot, G., Matthews, R., McVittie, A., Barnes, A., Rees, B., Moxey, A. & Williams, A. 2008. UK marginal abatement cost curves for the agriculture and land use, land use change and forestry sectors out to 2022, with qualitative analysis of options to 2050. Final Report to the Committee on Climate Change, Report No. RMP4950. Edinburgh: SAC. 152pp.Google Scholar
Moxey, A. 2011. Illustrative economics of peatland restoration. Report to IUCN UK Peatland Programme. Edinburgh, UK: IUCN UK Peatland Programme.Google Scholar
Read, D. J., Freer-Smith, P. H., Morison, J. I. L., Hanley, N., West, C. C. & Snowdon, P. (eds) 2009. Combating climate change – a role for UK Forests: Main Report. An Assessment of the potential of the UK's trees and woodlands to mitigate and adapt to climate change. Edinburgh: The Stationary Office.Google Scholar
Royal Society of Edinburgh. 2008. Committee of Inquiry into the Future of Scotland's Hills and Islands. Edinburgh, UK: The Royal Society of Edinburgh.Google Scholar
Royal Society of Edinburgh. 2011. Facing up to climate change: breaking the barriers to a low-carbon Scotland. Report of the Committee of Inquiry, March 2011. 186pp. Report and evidence collected available on line at www.royalsoced.org.uk.Google Scholar
RPA & Cambridge Econometrics. 2008. The Economic Impact of Scotland's Natural Environment. Scottish Natural Heritage Commissioned Report 304 (ROAME No. R07AA106). Inverness, UK: SNH.Google Scholar
Scottish Government. 2010. Management of Carbon-Rich soils – overview and Discussion paper. http://www.scotland.gov.uk/Resource/Doc/921/0109512.pdf. Accessed 10/07/ 2012.Google Scholar
Scottish Government. 2011. Final Results from 2011 June Agricultural Census. http://www.scotland.gov.uk/Publications/2011/09/27083355/0; Accessed 31/05/2012.Google Scholar
Scottish Government. 2012. http://www.scotland.gov.uk/Publications/2010/09/28094926/0; Accessed 31/05/2012.Google Scholar
Scottish Renewables. 2010. www.scottishrenewables.comGoogle Scholar
SEPA. 2009. The River Basin Management Plan for the Scotland river basin district 2009–2015, Summary. Stirling, UK: Scottish Environment Protection Agency.Google Scholar
SEPA. 2010. Trends in organic carbon in Scottish rivers and lochs. Stirling, UK: Scottish Environment Protection Agency.Google Scholar
SNH. 2004. Scotland's Biodiversity, it's in your hands. Edinburgh: Scottish Executive.Google Scholar
Soil Survey of Scotland Staff. 1984. Organization and methods of the 1:250 000 Soil Survey of Scotland. Aberdeen, UK: The Macaulay Institute for Soil Research.Google Scholar
Towers, W., Grieve, I. C., Hudson, G., Campbell, C. D., Lilly, A., Davidson, D. A., Bacon, J. R., Langan, S. J. & Hopkins, D. W. 2006. Scotland's Soil Resource – Current State and Threats. Environmental Research Report 2006/01. Edinburgh, UK: Scottish Government.Google Scholar
Towers, W., Sing, L., Ray, D. & Crow, P. 2011. Woodland Expansion GIS project. Report to the Woodland Expansion Advisory Group. Edinburgh, UK: Forestry Commission Scotland. http://www.forestry.gov.uk/website/forestry.nsf/byunique/infd-8meebv; Accessed 31/05/2012.Google Scholar