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Management of Caves

  • David Shaw Gillieson
Chapter

Abstract

People have used caves in many ways for tens of thousands of years and only recently recognized their recreational, aesthetic, and scientific value. However, this has not prevented their degradation and some suggest the carrying capacity of a cave is effectively zero. Caving results in a variety of impacts on the physical cave environment, although not equally for all caves or every part of the cave, which is then a challenge for management is to correctly evaluate the relative vulnerability of cave passages. These impacts can arise because tourist caves require physical alteration of natural passages, installation of lighting, pathways, platforms, and associated infrastructure. Cave fauna are impacted by alteration of cave hydrology, temperatures, lighting conditions, and carbon dioxide levels. Resulting invasive plants, desiccation of cave formations, and localized sedimentation highlight the need for effective ongoing monitoring of the cave atmosphere, water quality, and particulate deposition. Even scientific researches have impact; therefore, proposed research projects must minimize damage and maximize benefit for all cave stakeholders. Cave inventories are important for documenting valuable cave features, and they also allow for inter-cave comparisons and help with management classification and/or zoning. More enlightened management regimes consider good relations with park neighbors as essential and parks are run using principles of adaptive management. Cave managers should embrace the new management paradigms whilst conserving what are essentially nonrenewable resources.

Keywords

Cave System Drip Water Protected Area Management Cave Entrance Cave Environment 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

References

  1. Aley T (1976) Caves, cows and carrying capacity. In: National cave management symposium proceedings 1975, Speleobooks, Albuquerque, pp 70–71Google Scholar
  2. Aley T (2004) Tourist caves: algae and lampenflora. In: Gunn J (ed) The encyclopedia of caves and karst science. Taylor and Francis – Routledge, New York, pp 733–7734Google Scholar
  3. Bastian F, Alabouvette C (2009) Lights and shadows on the conservation of a rock art cave: the case of Lascaux Cave. Int J Speleol 38:55–60Google Scholar
  4. Bodenhamer HG (1995) Monitoring human caused changes with visitor impact mapping. In: Proceedings 1995 national cave management symposium, Bloomington, Indiana, pp 28–37Google Scholar
  5. Buecher RH (1995) Footprints, routes, and trails: methods for managing pathways in the cave environment. In: Proceedings 1995 national cave management symposium, Bloomington, Indiana, pp 47–50Google Scholar
  6. Bunting BW (1998) The impact of recreational caving on the physical environment of wild caves. Unpublished M. Sc. thesis, University of Waikato, Hamilton, New Zealand, 171 pGoogle Scholar
  7. Bunting BW, Megan R, Balks MR (2001) A quantitative method for assessing the impacts of recreational cave use on the physical environment of wild caves. ACKMA J 44:10–18Google Scholar
  8. Calaforra JM, Fernandez-Cortez A, Sanchez-Martos F et al (2003) Environmental control for determining human impact and permanent visitor capacity in a potential show cave before tourist use. Environ Conserv 30:160–167CrossRefGoogle Scholar
  9. Cigna AA (1993) Environmental management of tourist caves. Environ Geol 21:173–180CrossRefGoogle Scholar
  10. Culver DC, Pipan T (2009) The biology of caves and other subterranean habitats. Oxford University Press, OxfordGoogle Scholar
  11. Cunningham KI, Northup DE, Pollastro RM et al (1995) Bacteria, fungi and biokarst in Lechuguilla Cave, Carlsbad Caverns National Park, New Mexico. Environ Geol 25:2–8CrossRefGoogle Scholar
  12. Davidson P, Black R (2007) Voices from the profession: principles of successful guided cave interpretation. J Interpret Res 12:25–44Google Scholar
  13. De Freitas CR, Littlejohn RN (1987) Cave climate: assessment of heat and moisture exchange. J Clim 7:553–69CrossRefGoogle Scholar
  14. Department of Conservation, New Zealand (1999) General policy and guidelines for cave and karst management in areas managed by the department of conservation. DOC, WellingtonGoogle Scholar
  15. Elliott WR (2000) Conservation of the North American cave and karst biota. In: Wilkens H, Culver DC, Humphreys WF (eds) Subterranean ecosystems: ecosystems of the world, 30. Elsevier, Amsterdam, pp 665–689Google Scholar
  16. Elliott WR, Aley T (2006) Karst conservation in the Ozarks: forty years at Tumbling Creek Cave. In: Proceedings of the 2005 national cave and karst management symposium, Albany, pp 204–214Google Scholar
  17. Ganter JH (1989) Cave exploration, cave conservation: some thoughts on compatibility. NSS News 47(10):249–253Google Scholar
  18. Gillieson DS (1996) Caves: processes, development, management. Blackwell, OxfordGoogle Scholar
  19. Griffiths P, Ramsey C (2005) Best management practices for palaeontological and archaeological cave resources. ACKMA J 58:27–31Google Scholar
  20. Hamilton-Smith E (2004) Tourist caves. In: Gunn J (ed) The encyclopedia of caves and karst science. Taylor and Francis – Routledge, New York, pp 726–730Google Scholar
  21. Horne G (2005) Cave management guidelines for western mountain national parks of Canada. In: Proceedings 2005 national cave and karst management symposium, Albany, pp 53–61Google Scholar
  22. Hunter AJ, Northup DE, Dahm CN et al (2004) Persistent coliform contamination in Lechuguilla Cave pools. J Cave Karst Stud 66:102–110Google Scholar
  23. James JM (2004) Tourist caves: air quality. In: Gunn J (ed) The encyclopedia of caves and karst science. Taylor and Francis – Routledge, New York, pp 730–731Google Scholar
  24. Jenolan Caves Reserve Trust (1995) Determining an environmental and social carrying capacity for Jenolan Caves reserve, Applying a visitor impact management system. JCRT, BathurstGoogle Scholar
  25. Kell N (2002) Re-lighting Newdegate Cave. ACKMA J 47:40–43Google Scholar
  26. Kiernan K (1988) The management of soluble rock landscapes: an Australian perspective. Speleological Research Council, SydneyGoogle Scholar
  27. Lewis JJ (1996) Bioinventory as a management tool. In: Proceedings 1995 cave management symposium, Indiana Karst Conservancy, Indianópolis, pp 228–36Google Scholar
  28. Phillips A (2003) Turning ideas on their head: the new paradigm for protected areas. Background. Paper for the world parks congress, Durban, Sept 2003Google Scholar
  29. Spate A, Hamilton-Smith E (1991) Cavers impacts – some theoretical and applied considerations. Cave Manag Aust 9:20–30Google Scholar
  30. Spate AP, Moses C (1994) Impacts of high pressure cleaning: a case study at Jenolan. Cave Manag Aust 10:45–8Google Scholar
  31. Tattersall I, Schwartz JH (2001) Extinct humans. CO Westview Press, BoulderGoogle Scholar
  32. Tercafs R (1993) The protection of the subterranean environment: conservation principles and management tools. In: Carmacho AI (ed) The natural history of biospeleology. Monografias Museo Nacional de Ciencias Naturales, MadridGoogle Scholar
  33. Uhl PJ (1981) Photomonitoring as a management tool. In: Proceedings 8th international congress of speleology, Kentucky National Speleological Society, Bowling Green, pp 476–478Google Scholar
  34. Villar E, Fernandez PL, Gutierrez I et al (1986) Influence of visitors on carbon dioxide concentrations in Altamira Cave. Cave Sci 13(1):21–3Google Scholar
  35. Watson J, Hamilton-Smith E, Gillieson D et al (1997) Guidelines for cave and karst protected areas. World Conservation Union (IUCN), GlandGoogle Scholar
  36. Webb R (1995) Minimal impact caving code. ACKMA J 19:11–13Google Scholar
  37. Wilde KA, Williams PW (1988) Environmental monitoring of karst and caves. In: Proceedings of a symposium on environmental monitoring in New Zealand, with emphasis on protected natural areas, Otago University, NZ Department of Conservation, Albany, pp 82–90Google Scholar
  38. Williams PW (2008) World Heritage caves and karst: a thematic study. IUCN, GlandGoogle Scholar

Copyright information

© Springer Science+Business Media B.V. 2011

Authors and Affiliations

  1. 1.School of Earth & Environmental SciencesJames Cook UniversityCairnsAustralia

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