Skip to main content

Thank you for visiting You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

Density and abundance of badger social groups in England and Wales in 2011–2013


In the United Kingdom, European badgers Meles meles are a protected species and an important wildlife reservoir of bovine tuberculosis. We conducted a survey of badger dens (main setts) in 1614 1 km squares across England and Wales, between November 2011 and March 2013. Using main setts as a proxy for badger social groups, the estimated mean density of badger social groups in England and Wales was 0.485 km−2 (95% confidence interval 0.449–0.521) and the estimated abundance of social groups was 71,600 (66,400–76,900). In the 25 years since the first survey in 1985–88, the annual rate of increase in the estimated number of badger social groups was 2.6% (2.2–2.9%), equating to an 88% (70–105%) increase across England and Wales. In England, we estimate there has been an increase of 103% (83–123%) in badger social groups, while in Wales there has been little change (−25 to +49%).


European badgers Meles meles are the focus of intense public debate in the United Kingdom. They are an iconic wildlife species in British society1 and are protected under U.K. and European legislation. In the U.K. and Republic of Ireland they are also a reservoir of Mycobacterium bovis, the causative agent of tuberculosis in badgers and cattle2. Bovine tuberculosis (TB) is a major animal health challenge in the U.K. that results in substantial financial losses to taxpayers and farmers3. Control of TB in cattle is complicated by the reservoir of infection in badgers. Badger culling as a means of disease control is controversial, because of public concerns for badger conservation and welfare and because of the complex outcomes of culling for disease in badgers and cattle4,5,6,7.

Across much of the U.K. badgers live in social group territories with several shared dens, known as setts8. Because they are a protected species, any disturbance to individuals or their setts, requires a license from government9, which must take into account their conservation and population status. The size of the badger population in England and Wales is the subject of high levels of public interest and wide-ranging speculation because of the lack of recent data10. Therefore, it is important for the public and governments to have robust knowledge of badger populations.

There have been two surveys of badger populations in Great Britain that employed the same methodology, consisting of field surveys for badger setts in a random sample of 1 km squares, stratified by the U.K. landscape classification (Land Class Group) system11. The first survey in 1985–8812 covered 2455 1 km squares and the second, in 1994–9713, resurveyed 2271 of these and an additional 307 squares. To relate their findings to numbers of social groups, both surveys assumed that one main sett was present in each social group territory12,13. The number of badger social groups in Great Britain was estimated to have increased from 41,894 (95% confidence intervals 37,490–46,298) in the 1980s to 50,241 (45,914–54,568) in the 1990s, i.e. an increase of 24%12,13. There has been no survey of badger setts over the whole of Great Britain since the 1990s. A survey of Scotland was conducted in 2007–0914 and resulted in an estimate of 7,300–11,200 social groups, with central estimates of 8955 or 9370, depending on the statistical assumptions made. Although this survey was not directly comparable to the earlier surveys, the authors concluded that their data suggested there could have been a substantial increase in the number of setts in Scotland since the 1990s but could not rule out this difference arising from differences in survey protocols14, underlining the importance of applying consistent methodology between surveys. In Northern Ireland, which also forms part of the U.K., badger surveys employing the same methodology were conducted in 1990–9315 and again in 2007–0816, the latter of which estimated the presence of 7,600 (6,200–9,000) social groups, with no significant change in abundance between the two surveys.

We conducted a survey of badger setts in England and Wales in 2011–13 and report the results of our estimates of the abundance of badger social groups. We compare these to earlier surveys and compile our results with the published outcomes of the most recent surveys of Scotland and Northern Ireland, to derive estimates of the abundance of badger social groups in Great Britain and the United Kingdom.

While badger sett surveys are well suited to estimating the abundance of social groups, on their own they are limited in their suitability for estimating populations of individual animals17. This is principally because sett characteristics are a poor predictor of badger numbers18 and group size can vary widely19 making it difficult to obtain a representative mean across an adequate sample. We are currently undertaking work to estimate group sizes across a large sample of setts in order to estimate badger population size.


Survey coverage

We surveyed 1702 1 km squares. Of these, 1614 (95%) squares were included in our analyses. The remaining 88 squares were removed, because in each case access to land was denied for >50% of the area. The 1614 squares comprised 1411 squares in England and 203 squares in Wales, leading to survey coverage of 1330 km2 (1.0% of land area) in England and 184 km2 (0.9%) in Wales.

Badger sett distribution

We estimate that active main badger setts are present in 34.4% (95% confidence intervals 32.2–36.7%) of rural 1 km squares in England and Wales and that active setts of any type are present in 56.3% (95% confidence intervals 53.9–58.6%) of rural 1 km squares.

This represents an increase of 14.4% points (95% confidence intervals 11.5–17.3%, i.e. an increase from 20.0% to 34.4%) since the 1985–88 survey in the proportion of 1 km squares that contain a main sett and 21.2% points (17.8–24.5, i.e. an increase from 35.1% to 56.3%) in the proportion that contain any badger sett.

Badger sett density and abundance

The estimated mean density of main setts in rural England and Wales was 0.485 km−2 (0.449–0.521). The density of badger setts varied among Land Class Groups (Table 1). The total number of main badger setts and hence the number of social groups, in rural England and Wales in 2011–13 was estimated to be 71,600 (66,300–76,900).

Table 1 Results of a badger sett survey in England and Wales in 2011–13. Land Class Groups (LCG) are described in Supplementary Table 1 and their distribution is shown in Supplementary Figure 1. Data from 1985–88 and 1994–97 are from earlier surveys. Small discrepancies may arise between strata totals as a result of within-stratum variation and rounding

Combining our survey results with the 2007–09 survey of Scotland14 and assuming no change in Scotland since then, results in an estimate of 81,000 (75,400–86,600) social groups in Great Britain. Combining this estimate for Great Britain with the 2007–08 survey of Northern Ireland16, again assuming no change in Northern Ireland since then, results in an estimate of 88,600 (82,900–94,400) social groups in the United Kingdom.

Changes in badger sett density and abundance

Comparing the results of the present survey with the first survey indicates that the estimated density of main setts in England and Wales is now 88% (70–105%) greater than in 1985–88, suggesting an estimated average annual rate of increase of approximately 2.6% (2.2–2.9%). Estimated annual rates of increase between 1985–88 and 1994–97 (0.6–3.5%) and between 1994–97 and the present survey (2.1–3.3%) did not differ significantly (p = 0.21, assuming a single rate exponential in each time interval). In order to realize this increase, the abundance of badger social groups in England and Wales is likely to have increased by 27,000–40,000 over the 25 years between the median dates of the first and the most recent surveys. The pattern of change in estimated social group density differed between England and Wales. Since 1985–88, the estimated number of social groups has increased by 103% (83–123%) in England. By contrast estimated sett densities have remained approximately constant in Wales (change of between −25 and +49%) (Table 1, Figure 1).

Figure 1
figure 1

Estimates of badger main sett (a) density and (b) abundance in England and Wales and by Land Class Group in three surveys.

Shaded blocks indicate 95% confidence intervals for means. No main setts were identified in LCG 7 in the 2011–13 survey.

Changes in the estimated density of main setts varied among Land Class Groups (LCGs) (Table 1, Figure 2). Increases were observed in the more widespread LCGs (Arable 1, Arable 2, Pastoral 4, Pastoral 5 and Marginal Upland 6). There may also have been an increase in LCG Arable 3, but the large relative uncertainty associated with the estimated change meant that a decline could not be ruled out (Figure 2). The small area of LCG Arable 3 meant the effect of this uncertainty on the estimation of change in overall numbers of main setts is small.

Figure 2
figure 2

Estimates of changes in badger main sett (a) density and (b) abundance in England and Wales and by Land Class Group between 1985–88 and 2011–13.

Shaded blocks indicate 95% confidence intervals for estimates of change. Where these do not overlap the red line, indicating no change, the change is considered statistically significant.


A robust estimate of the current badger population in England and Wales is not yet available because assessment of variation in the number of individual badgers in social groups is ongoing. However, there was no primary assessment of social group size in either of the previous surveys12,13. Therefore, while we can infer change in the abundance of social groups, we cannot ever know whether social group sizes have increased, remained constant or declined between surveys. A measure of social group abundance may nonetheless be at least as useful as a total population estimate, despite the intuitive appeal of the latter, because a) it is less likely to vary at fine temporal scales, i.e. numbers per group may vary between years but numbers of social groups may be more stable20, b) it is epidemiologically informative because of the importance of social structure to TB transmission in badgers7 and c) because assessments of conservation and other management actions are often made at a social group level9.

Although our protocol was similar to previous surveys in most respects, a large proportion of squares in the earlier studies were surveyed by experienced volunteers (73% in 1985–88 and 68% in 1994–97) as opposed to trained professional surveyors, as in our survey. Clearly, we cannot retrospectively assess the quality of earlier surveys, but both the 1980s and 1990s surveys also used professionals to conduct a proportion of their surveys and so they were able to test surveyor reliability in identifying sett types. They found that fewest problems arose with the classification of main setts from other sett types. They also found no consistent patterns in sett encounter rates among volunteers and professionals and so were content to pool data from all surveyors for analysis12,13. While we are confident in our professional estimates of current main sett abundance, it remains a possibility that previous, partly amateur, surveys did not identify setts with the same success or classify setts in the same way as this survey, potentially leading to some additional error in our estimates of change between surveys. Nonetheless, our survey represents a robust, national-scale assessment of badger social group abundance in 2013. It is comparable in approach to those based on sett surveys conducted in 1985–88 and 1994–97 and so is the best and probably only, basis on which to assess badger population change at the national scale.

This survey highlights a general increase in estimates of badger social group density/abundance, with some regional variation. The marked increase in estimated main sett density in LCG Arable 1, which is found across much of south central England, is particularly noteworthy because density in this landscape did not appear to have changed between the 1980s and 1990s13. The difference in the estimated magnitude of change in England and Wales suggests that in addition to landscape effects, there are further regional effects on population change.

At the landscape scale, there is a general association between the density of badgers and the density of setts18. The long term increase in the estimated abundance of badger main setts reported here is likely to indicate an increase in badger numbers though the magnitude of that increase cannot be determined, as the general relationship between social group abundance and population size has not been established. Long term badger population monitoring at a ~7 km2 site at Woodchester Park in Gloucestershire, where the density of social groups has varied from 3–4 km−2, showed that the number of groups remained relatively constant over time, while badger population size more than doubled from 1982 to a peak in 1999 and subsequently declined to 200520. In a 22 km2 study area in Sussex the number of main setts more than doubled within a 20 year period, though a proportion of this increase was due to large territories being subdivided21,22. At Wytham Woods in Oxfordshire, a long-term study of an undisturbed population showed doubling in population size between 1987 and 1996, followed by a decline in the late 1990s and further increases thereafter23. Thus, there is ample scope for badger populations to vary over time, because of changes in both the abundance and size of social groups. Furthermore, owing to the long intervals between the national sett surveys, we cannot use these data to predict whether the increase in estimated social group abundance observed here is ongoing.

We cannot ascribe the observed changes in estimated badger social group abundance over the ~25 years to 2013 to specific factors with any degree of certainty. However, in common with the conclusions of the previous badger survey13, it seems likely to be the ongoing result of species protection and changes in habitat quality. Further analyses may reveal correlations between land management and change in social group density, but cause and effect is not likely to be firmly established.

Other carnivores living in Britain have increased their populations over similar periods. Increases in the numbers of red foxes Vulpes vulpes shot by gamekeepers are apparent from the National Gamebag Census24, which indicates an increase of 97% in England and 67% in Wales between 1984–2009, with particularly marked increases of 112% in what that scheme refers to as the “easterly lowlands” of England and Wales and 86% in the “westerly lowlands” of England and Wales. Polecat Mustela putorius gamebag records exhibited a 72% increase from 1984–2009 in the easterly lowlands but a 39% decrease in the westerly lowlands24, though the utility of these records may be compromised by species protection and consequent underreporting of captures. Otter Lutra lutra surveys in England in 1977–79 recorded their presence in 170 of 2940 sites (5.8%) but this had increased 10-fold to 58.8% by 2009–1025.

The implications of increasing badger populations are numerous. Badgers are the largest terrestrial carnivore in the British Isles. They feed across numerous trophic levels and largely eat soil invertebrates, but will also prey upon ground nesting birds, hedgehogs and other vertebrates8,22. Evaluation of the ecological impact of badger culling during the Randomised Badger Culling Trial identified an increase in fox abundance associated with reductions in badger density26 while reciprocal relationships between hedgehog Erinaceus europaeus and badger distributions suggest that increasing badger numbers might have had a negative impact on hedgehogs27. In terms of tuberculosis epidemiology, at a local level, disease prevalence and incidence appears to vary with mobility among groups28 and prevalence has been shown to be higher in smaller social groups29. Consequently, despite a broad landscape scale correlation between the incidence of TB in cattle and the distribution of badgers30, badger social group density alone may not predict patterns of TB infection in badgers or cattle.


Sampling design

As in both previous national surveys, sampling was based on the Institute of Terrestrial Ecology (now Centre for Ecology and Hydrology) Land Classification System11. The distribution of the seven Land Class Groups is shown in Figure 3 and a basic description provided in Table 2. We selected new survey squares (Figure 4) using a disproportionate stratified random sampling method to obtain a representative sample of the landscape in England and Wales while concentrating sampling effort on strata with greater badger density12,13 and thereby improving survey precision. See below for details of how the survey data are analysed within survey strata. Squares which contained greater than 50% urban land or water were discarded and replaced with another randomly selected square of the same land class group and general location. Therefore, in line with the previous surveys, all survey squares were predominantly rural.

Table 2 Descriptions of the seven Land Class Groups in England & Wales
Figure 3
figure 3

Distribution of the seven Land Class Groups in England and Wales.

Urban areas are not coloured. Map created in ESRI ArcGIS 10.1.

Figure 4
figure 4

Distribution of surveyed 1 km squares in England and Wales.

Map created in ESRI ArcGIS 10.1.

Field surveys

Surveys were carried out by trained badger surveyors, all employed by the National Wildlife Management Centre, who worked to a Standard Operating Procedure. In common with the previous surveys, fieldwork was conducted in the autumn, winter and spring, when vegetation is at its lowest and badger setts are easier to find. All surveys in this study were conducted between 1st November and 31st March, starting in November 2011 and finishing in March 2013. No pre-existing survey information for any squares was available or provided to surveyors, so surveys were conducted “blind”. All land within the 1 km square for which access permission had been granted was surveyed on foot. All field boundaries were surveyed initially and badger trails (runs) radiating from the boundaries into the middle of fields were followed if there was a possibility they would lead to a sett e.g. if there was a hollow, pond, small copse etc. in the field. Rough and wooded areas and around buildings were surveyed. Surveyors walked both sides of linear features and woodland and other rough terrain was surveyed using transects. Particularly difficult terrain was surveyed by teams of staff walking in parallel within visual contact.

As with the previous two surveys, each sett found within a square was recorded on the same map and identified by a sequential number. A sett was defined as either a single hole or a series of a few or many holes. For this survey, setts were classified as either a main sett or ‘other’ sett. ‘Other setts’ combined the annex, subsidiary and outlier sett categories used in the previous two surveys12,13. Setts were classified on the basis of size, number of holes, degree of use of holes and pathways between holes and running to and from setts and the size of spoil heaps31, following the guidelines used in the previous surveys. The numbers of active, partially active and disused holes were recorded for each sett. The co-ordinates at the centre of each recorded sett were recorded using a handheld Global Positioning System (GPS).


The survey was analysed as a set of observations in a random sample of squares stratified by LCG. The density of main setts was estimated within LCG strata from the observed number of setts and the total area surveyed in each stratum. The density across England and Wales was estimated as the mean of densities observed within each of the strata weighted by the area of each LCG within the area to which the estimate applied. Similarly, standard errors of density estimates were derived from weighted sum of within-stratum observed variances12. The proportion of squares that contained an active sett or main sett was estimated from the weighted sum of the number of squares that were found to contain a sett or main sett. Confidence intervals for densities and numbers of setts were derived assuming normally dispersed errors. Confidence intervals for proportions of squares containing a sett or main sett were estimated from a weighted random sample from modified Jeffrey's intervals for binomial proportions32.

Survey data for England and Wales from the 1985–88 badger survey of Great Britain were extracted from the survey raw data, which were accessed under license from the Joint Nature Conservation Committee and were re-analysed using the same updated LCG area estimates used in the analysis of the most recent survey to provide a baseline against which to estimate changes.

Raw survey data for the 1994–97 survey are not in the public domain. Hence, a more ad hoc analysis was undertaken. Main sett densities and LCG areas and within-strata standard errors13,33 were used to estimate the number of main setts in Great Britain. Scottish survey results from the 1985–88 survey were inflated by a factor describing the small increase in the number of main setts observed between 1985–88 and 1994–9713. The resulting data set was analysed using the method described above to provide an estimate of the number of setts per LCG in Scotland. Finally Scottish LCG densities were subtracted from those for Great Britain, to provide an estimate of average LCG strata densities across England and Wales in the 1994–97 survey and standard errors of estimates. Densities were combined, weighted by LCG area to provide an estimate of average sett density across England and Wales. The estimate was produced chiefly for the purpose of providing an indication of whether change observed between the two more readily accessible surveys showed evidence of varying between the two time intervals examined.


  • Cassidy, A. Vermin, victims and disease: UK framings of badgers in and beyond the bovine TB controversy. Sociol. Rural. 52, 192–214; 10.1111/j.1467-9523.2012.00562.x (2012).

    Article  Google Scholar 

  • Gortazar, C. et al. The status of tuberculosis in European wild mammals. Mammal Rev. 42, 193–206; 10.1111/j.1365-2907.2011.00191.x (2012).

    Article  Google Scholar 

  • Godfray, H. C. J. et al. A restatement of the natural science evidence base relevant to the control of bovine tuberculosis in Great Britain. Proc. R. Soc. B. 280, 20131634; 10.1098/rspb.2013.1634 (2013).

    Article  PubMed  Google Scholar 

  • Donnelly, C. A. et al. Impact of localized badger culling on tuberculosis incidence in British cattle. Nature 426, 834–837; 10.1038/nature02192 (2003).

    CAS  ADS  Article  PubMed  Google Scholar 

  • Donnelly, C. A. et al. Positive and negative effects of widespread badger culling on tuberculosis in cattle. Nature 439, 843–846; 10.1038/nature04454 (2006).

    CAS  ADS  Article  PubMed  Google Scholar 

  • Jenkins, H. E., Woodroffe, R. & Donnelly, C. A. The duration of the effects of repeated widespread badger culling on cattle tuberculosis following the cessation of culling. PLOS ONE 5, e9090; 10.1371/journal.pone.0009090 (2010).

    CAS  ADS  Article  PubMed  PubMed Central  Google Scholar 

  • McDonald, R. A., Delahay, R. J., Carter, S. P., Smith, G. C. & Cheeseman, C. L. Perturbing implications of wildlife ecology for disease control. Trends Ecol. Evol. 23, 53–56; 10.1016/j.tree.2007.10.011 (2008).

    Article  PubMed  Google Scholar 

  • Neal, E. G. & Cheeseman, C. L. Badgers. (London, Poyser Natural History, 1998).

  • Delahay, R. J. et al. Managing conflict between humans and wildlife: trends in licensed operations to resolve problems with badgers Meles meles in England. Mammal Rev. 39, 53–66; 10.1111/j.1365-2907.2008.00135.x (2009).

    Article  Google Scholar 

  • Page, R. Country diary: badgers are out of control. Daily Telegraph, (18 June 2013). Downloaded 27 July 2013.

  • Bunce, R. G. H., Barr, C. J. & Whittaker, H. A. Land classes in Great Britain: preliminary descriptions for use of the Merlewood method of land classification. (Grange-over-Sands, Institute of Terrestrial Ecology, 1981).

  • Cresswell, P., Harris, S. & Jefferies, D. J. The history, distribution, status and habitat requirements of the badger in Britain. (Peterborough, Nature Conservancy Council, 1990).

  • Wilson, G., Harris, S. & McLaren, G. Changes in the British badger population 1988 to 1997. (London, People's Trust for Endangered Species, 1997).

  • Rainey, E., Butler, A., Bierman, S. & Roberts, A. M. I. Scottish Badger Distribution Survey 2006 – 2009: estimating the distribution and density of badger main setts in Scotland. (Scottish Badgers and Biomathematics and Statistics Scotland, 2009).

  • Feore, S. M. The distribution and abundance of the badger Meles meles L in Northern Ireland. (PhD thesis, Queen's University Belfast, 1994).

  • Reid, N., Etherington, T. R., Wilson, G. J., Montgomery, I. & McDonald, R. A. Monitoring and population estimation of the European badger Meles meles in Northern Ireland. Wildlife Biol. 18, 46–57; 10.2981/11-016 (2011).

    Article  Google Scholar 

  • Wilson, G. J. & Delahay, R. J. A review of methods to estimate the abundance of terrestrial carnivores using field signs and observation. Wildlife Res. 28, 151–164; 10.1071/WR00033 (2001).

    Article  Google Scholar 

  • Lara-Romero, C., Virgos, E. & Revilla, E. Sett density as an estimator of population density in the European badger (Meles meles). Mammal Rev. 42, 78–84; 10.1111/j.1365-2907.2011.00194.x (2012).

    Article  Google Scholar 

  • Wilson, G. J., Delahay, R. J., de Leeuw, A. N. S., Spyvee, P. D. & Handoll, D. Quantification of badger (Meles meles) sett activity as a method of predicting badger numbers. J. Zool. 259, 49–56; 10.1017/S0952836902002947 (2003).

    Article  Google Scholar 

  • Delahay, R. J. et al. Long-term temporal trends and estimated transmission rates for Mycobacterium bovis infection in an undisturbed high-density badger (Meles meles) population. Epidemiol. Infect. 141, 1445–1456; 10.1017/S0950268813000721 (2013).

    CAS  Article  PubMed  Google Scholar 

  • Ostler, J. R. & Roper, T. J. Changes in size, status and distribution of badger Meles meles L. setts during a 20 year period. Z. Säugertierk. 63, 200–209 (1998).

    Google Scholar 

  • Roper, T. J. Badger. (London, HarperCollins, 2010).

  • Macdonald, D. W., Newman, C., Nouvellet, P. M. & Buesching, C. D. An analysis of Eurasian badger (Meles meles) population dynamics: Implications for regulatory mechanisms. J. Mammal. 90, 1392–1403; 10.1644/08-MAMM-A-356R1.1 (2009).

    Article  Google Scholar 

  • Aebischer, N. J., Davey, P. D. & Kingdon, N. G. National Gamebag Census: Mammal Trends to 2009. (Game and Wildlife Conservation Trust, Fordingbridge, 2011) (

  • Crawford, A. Fifth Otter Survey of England 2009–2010. (Environment Agency, Bristol, 2010).

  • Trewby, I. D. et al. Experimental evidence of competitive release in sympatric carnivores. Biol. Lett. 4, 170–172; 10.1098/rsbl.2007.0516 (2008).

    Article  PubMed  Google Scholar 

  • Young, R. P. et al. Abundance of hedgehogs (Erinaceus europaeus) in relation to the density and distribution of badgers (Meles meles). J. Zool. 266, 81–87; 10.1111/j.1469-7998.2006.00078.x (2006).

    Article  Google Scholar 

  • Vicente, J., Delahay, R. J., Walker, N. J. & Cheeseman, C. L. Social organization and movement influence the incidence of bovine tuberculosis in an undisturbed high-density badger Meles meles population. J. Anim. Ecol. 76, 348–360; 10.1111/j.1365-2656.2006.01199.x (2007).

    CAS  Article  PubMed  Google Scholar 

  • Woodroffe, R. et al. Social group size affects Mycobacterium bovis infection in European badgers (Meles meles). J. Anim. Ecol. 78, 818–827; 10.1111/j.1365-2656.2009.01545.x (2009).

    Article  PubMed  Google Scholar 

  • Wilesmith, J. W. Epidemiological features of bovine tuberculosis in cattle herds in Great Britain. J. Hyg-Cambridge 90, 159–176 (1983).

    CAS  Article  Google Scholar 

  • Kruuk, H. Spatial organization and territorial behavior of the European badger Meles meles. J. Zool. 184, 1–19; 10.1111/j.1469-7998.1978.tb03262.x (1978).

    Article  Google Scholar 

  • Brown, L. D. et al. Interval estimation for a binomial proportion. Stat. Sci. 16, 101–133 (2001).

    MathSciNet  MATH  Google Scholar 

  • Wilson, G. J. Patterns of Population Change in the Eurasian Badger (Meles meles) in Britain, 1988 – 1997. (PhD Thesis, University of Bristol, 1998).

Download references


We are grateful to the thousands of landowners for their kind co-operation in granting access to their land. This study was funded by the Department for Environment, Food and Rural Affairs, as part of England and Wales national research activities. Fieldwork was conducted by staff of the National Wildlife Management Centre. Access to data from the 1985–88 survey was licensed by the Joint Nature Conservation Committee, to whom the rights of the Nature Conservancy Council had passed.

Author information

Authors and Affiliations



The project was designed by J.J., G.J.W., R.A.M. and R.M. and run by J.J. R.M. analysed the data. The paper was written by J.J., G.J.W., R.M., R.J.D. and R.A.M.

Ethics declarations

Competing interests

The authors declare no competing financial interests.

Rights and permissions

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivs 3.0 Unported License. To view a copy of this license, visit

Reprints and Permissions

About this article

Cite this article

Judge, J., Wilson, G., Macarthur, R. et al. Density and abundance of badger social groups in England and Wales in 2011–2013. Sci Rep 4, 3809 (2014).

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI:

Further reading


By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.


Quick links

Nature Briefing

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

Get the most important science stories of the day, free in your inbox. Sign up for Nature Briefing