Difference between revisions of "Groundwater access"

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* [http://www.bgs.ac.uk/research/groundwater/international/africangroundwater/home.html Groundwater resilience to climate change in Africa.] Keyworth, Nottingham. British Geological Survey 2011.
 
* [http://www.bgs.ac.uk/research/groundwater/international/africangroundwater/home.html Groundwater resilience to climate change in Africa.] Keyworth, Nottingham. British Geological Survey 2011.
 
* [http://www.un-igrac.org/resource/global-overview-saline-groundwater-occurrence-and-genesis-0 Global Overview of Saline Groundwater Occurrence and Genesis.] IGRAC, 2009.
 
* [http://www.un-igrac.org/resource/global-overview-saline-groundwater-occurrence-and-genesis-0 Global Overview of Saline Groundwater Occurrence and Genesis.] IGRAC, 2009.
* [http://www.iaea.org/technicalcooperation/documents/Brochures/sust-groundwater.pdf Sustainable Development of Groundwater Resources in  Southern and Eastern Africa.] International Atomic Energy Agency.
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* [http://web.archive.org/web/20151106164515/https://www.iaea.org/technicalcooperation/documents/Brochures/sust-groundwater.pdf Sustainable Development of Groundwater Resources in  Southern and Eastern Africa.] International Atomic Energy Agency.
 
* [http://www.rural-water-supply.net/en/resources/details/187 Siting of Drilled Water Wells - A Guide for Project Managers] RWSN Field Note 2010-5 (Cost Effective Boreholes Series). Carter, R., Chilton, J., Danert, K. et al. RWSN. St Gallen, Switzerland 2010.
 
* [http://www.rural-water-supply.net/en/resources/details/187 Siting of Drilled Water Wells - A Guide for Project Managers] RWSN Field Note 2010-5 (Cost Effective Boreholes Series). Carter, R., Chilton, J., Danert, K. et al. RWSN. St Gallen, Switzerland 2010.
  

Latest revision as of 00:09, 7 April 2016

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Rainwater (if given the chance to infiltrate) eventually becomes groundwater. Groundwater is advantageous to harvest as it is always accessible (in spite of the timing of the rainy season), has a high storage capacity with good water quality (usually), is resilient to inter-annual climate variability and has a low cost relative to alternative sources.

However, the height of the water table depends on a lot of factors: type of soils or rock beneath the surface, nearby reservoirs or rivers, and frequency or overall total abstraction of water from populations nearby. Also consider the quality of the groundwater. Is it too salty or near an agricultural runoff or sewage water area? Locate the infiltration or abstraction points where the water is least likely to be affected by pollutants.

Climate change considerations
Climate change affects the precipitation and temperature dynamics on a global scale, and hence will impact upon the supply and demand for water of local communities. Enhancing water storage capacity, both above and below ground, is widely accepted as a coping strategy against hydrological shocks such as floods and droughts.


Riverbed infiltration galleries small.jpg
Springwater collection
Subsurface harvesting systems small.jpg
Small rotary machines small.jpg
Jetting - Engine powered rotary jetting small.jpg


Field experiences


Akvorsr logo lite.png
RSR Project 473
Project Water4Tomorrow


Groundwater links


Acknowledgements