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These articlesprovides information for users of the near surface electrical resistivity model of Great Britain. This model has been developed as part of the DiGMapPlus program at BGS.
This document provides information for users of the near surface electrical resistivity model of Great Britain. This model has been developed as part of the DiGMapPlus program at BGS.


The resistivity of geological units is an important factor in engineering activities where the electrical characteristics of the ground are required, e.g. in earthing of electrical systems. The resistivity of the ground is dependent on a number of factors which include the porewater resistivity, the saturation and the geology.
The resistivity of geological units is an important factor in engineering activities where the electrical characteristics of the ground are required, e.g. in earthing of electrical systems. The resistivity of the ground is dependent on a number of factors which include the porewater resistivity, the saturation and the geology.


==Background==
==Background==
The near surface ‘electrical resistivity model of Great Britain’ has been developed from previous regional resistivity models carried out to inform the design of earthing systems for Western Power Distribution and United Kingdom Power Networks. This work is reported in Busby et al. (2012 and 2014).
The near surface ‘electrical resistivity model of Great Britain’ has been developed from previous regional resistivity models carried out to inform the design of earthing systems for Western Power Distribution and United Kingdom Power Networks. This work is reported in Busby et al. (2012<ref name="Busby 2012">BUSBY, J P, ENTWISLE, D, HOBBS, P, JACKSON, P, JOHNSON, N, LAWLEY, R, LINLEY, K, MAYR, T, PALMER, R, RAINES, M, REEVES, H, TUCKER, S and ZAWADZKA, J. 2012, A GIS for the planning of electrical earthing, ''Quarterly Journal of Engineering Geology and Hydrogeology'', 45, 379–390 </ref> and 2014<ref name="Busby 2014">BUSBY, J, LAWLEY, R, WHITE, J, JAMES, I, ENTWISLE, D, BARKWITH, A, HANNAM, J, PACHOCKA, M, MANSOUR, M, MAYR, T and DACCACHE, A. 2014, User Guide DiGMapPlus+ Engineering Properties: Resistivity dataset (version 1). British Geological Survey and National Soils Research Institute. British Geological Survey, Keyworth, Nottingham, UK. </ref>).


The resistivity model is derived using an effective medium methodology to calculate bulk resistivity (Berg, 2007). The BGS National Geotechnical Properties Database (Self, 2012) and information from the BGS Streams database (British Geological Survey, 2009) were utilised to parameterise the input variables in the resistivity calculation. The derived resistivity values were coupled to the geology of Great Britain described in the soil-parent material map (PMM) (Lawley, 2008) using a spatial GIS join. The soil-parent material map (PMM) of Great Britain (Lawley, 2008) describes the characteristics of the near surface zone from which soils develop. Typically, this material is the first geological unit encountered beneath the base of pedological soil. The PMM is derived from the BGS 1:50k scale geological map of Great Britain, known as DiGMapGB-50 (British Geological Survey, 2011). The PMM compilation combines data from the bedrock and superficial (drift) geological maps to produce a model of the surface geology.
The resistivity model is derived using an effective medium methodology to calculate bulk resistivity (Berg, 2007<ref name="Berg">BERG, C. 2007. An effective medium algorithm for calculating water saturations at any salinity or frequency. ''Geophysics '''''72''', E59–E67. </ref>). The BGS National Geotechnical Properties Database (Self, 2012<ref name="Self">SELF, S, ENTWISLE, D C and NORTHMORE, K. 2012. ''The structure and operation of the BGS National Geotechnical Properties Database. Version 2. ''Nottingham, UK, British Geological Survey, 68pp. (IR/12/056). [http://nora.nerc.ac.uk/20815/ http://nora.nerc.ac.uk/20815/]</ref>) and information from the BGS Streams database (British Geological Survey, 2009<ref name="BGS 2009">British Geological Survey. 2009. Conductivity in stream waters: Great Britain. G-Base Geochemical Map. British Geological Survey, Keyworth, Nottingham, UK. </ref>) were utilised to parameterise the input variables in the resistivity calculation. The derived resistivity values were coupled to the geology of Great Britain described in the soil-parent material map (PMM) (Lawley, 2008<ref name="Lawley">LAWLEY, R. 2008, The soil-parent material database: a user guide, British Geological Survey Open report, OR/08/034. </ref>) using a spatial GIS join. The soil-parent material map (PMM) of Great Britain (Lawley, 2008<ref name="Lawley"></ref>) describes the characteristics of the near surface zone from which soils develop. Typically, this material is the first geological unit encountered beneath the base of pedological soil. The PMM is derived from the BGS 1:50k scale geological map of Great Britain, known as DiGMapGB-50 (British Geological Survey, 2011<ref>British Geological Survey. 2011. Digital Geological Map of Great Britain 1:50 000 scale (DiGMapGB-50) data [CD-Rom]. Version 6.20. Keyworth, Nottingham: British Geological Survey. </ref>). The PMM compilation combines data from the bedrock and superficial (drift) geological maps to produce a model of the surface geology.


==References==


[[category: OR/14/030 Electrical Resistivity Model of Great Britain: User Guide | 01]]
[[category: OR/14/030 Electrical Resistivity Model of Great Britain: User Guide | 01]]

Latest revision as of 11:58, 10 August 2015

Entwisle, D C, White, J C, Busby, J P, Lawley R S and Cooke, I L. 2014. Electrical Resistivity Model of Great Britain: User Guide. British geological Survey. (OR/14/030).

These articlesprovides information for users of the near surface electrical resistivity model of Great Britain. This model has been developed as part of the DiGMapPlus program at BGS.

The resistivity of geological units is an important factor in engineering activities where the electrical characteristics of the ground are required, e.g. in earthing of electrical systems. The resistivity of the ground is dependent on a number of factors which include the porewater resistivity, the saturation and the geology.

Background

The near surface ‘electrical resistivity model of Great Britain’ has been developed from previous regional resistivity models carried out to inform the design of earthing systems for Western Power Distribution and United Kingdom Power Networks. This work is reported in Busby et al. (2012[1] and 2014[2]).

The resistivity model is derived using an effective medium methodology to calculate bulk resistivity (Berg, 2007[3]). The BGS National Geotechnical Properties Database (Self, 2012[4]) and information from the BGS Streams database (British Geological Survey, 2009[5]) were utilised to parameterise the input variables in the resistivity calculation. The derived resistivity values were coupled to the geology of Great Britain described in the soil-parent material map (PMM) (Lawley, 2008[6]) using a spatial GIS join. The soil-parent material map (PMM) of Great Britain (Lawley, 2008[6]) describes the characteristics of the near surface zone from which soils develop. Typically, this material is the first geological unit encountered beneath the base of pedological soil. The PMM is derived from the BGS 1:50k scale geological map of Great Britain, known as DiGMapGB-50 (British Geological Survey, 2011[7]). The PMM compilation combines data from the bedrock and superficial (drift) geological maps to produce a model of the surface geology.

References

  1. BUSBY, J P, ENTWISLE, D, HOBBS, P, JACKSON, P, JOHNSON, N, LAWLEY, R, LINLEY, K, MAYR, T, PALMER, R, RAINES, M, REEVES, H, TUCKER, S and ZAWADZKA, J. 2012, A GIS for the planning of electrical earthing, Quarterly Journal of Engineering Geology and Hydrogeology, 45, 379–390
  2. BUSBY, J, LAWLEY, R, WHITE, J, JAMES, I, ENTWISLE, D, BARKWITH, A, HANNAM, J, PACHOCKA, M, MANSOUR, M, MAYR, T and DACCACHE, A. 2014, User Guide DiGMapPlus+ Engineering Properties: Resistivity dataset (version 1). British Geological Survey and National Soils Research Institute. British Geological Survey, Keyworth, Nottingham, UK.
  3. BERG, C. 2007. An effective medium algorithm for calculating water saturations at any salinity or frequency. Geophysics 72, E59–E67.
  4. SELF, S, ENTWISLE, D C and NORTHMORE, K. 2012. The structure and operation of the BGS National Geotechnical Properties Database. Version 2. Nottingham, UK, British Geological Survey, 68pp. (IR/12/056). http://nora.nerc.ac.uk/20815/
  5. British Geological Survey. 2009. Conductivity in stream waters: Great Britain. G-Base Geochemical Map. British Geological Survey, Keyworth, Nottingham, UK.
  6. 6.0 6.1 LAWLEY, R. 2008, The soil-parent material database: a user guide, British Geological Survey Open report, OR/08/034.
  7. British Geological Survey. 2011. Digital Geological Map of Great Britain 1:50 000 scale (DiGMapGB-50) data [CD-Rom]. Version 6.20. Keyworth, Nottingham: British Geological Survey.