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14.3: Groundwater Extraction

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    Except in areas where groundwater comes naturally to the surface at a spring (a place where the water table intersects the ground surface), we have to construct wells in order to extract it. If the water table is relatively close to the surface, a well can be dug by hand or with an excavator, but in most cases we need to use a drill to go down deep enough. There are many types of drills that can be used; an example is shown in Figure \(\PageIndex{1}\). A well has to be drilled at least as deep as the water table, but in fact must go much deeper; first, because the water table may change from season to season and from year to year, and second, because when water is being pumped, the water level will drop, at least temporarily.

    Figure \(\PageIndex{1}\) A water-well drilling rig in operation near Nanaimo, B.C. In the photo on the right the well is being test-pumped with air pressure. The casing (yellow arrow) is about 40 centimeters in diameter.

    Where a well is drilled in unconsolidated sediments or relatively weak rock, it has to be lined with casing (steel pipe in most cases) in order to ensure that it doesn’t cave in. A specially designed well screen is installed at the bottom of the casing. The size of the holes in the screen is carefully chosen to make sure that it allows the water to move into the well freely, but prevents aquifer particles from entering the well. A submersible pump is typically used to lift water from within the well up to the surface where it is needed. The well shown in Figure \(\PageIndex{1}\) has casing that is about 40 centimeters in diameter, which might be typical for a municipal water supply well, or a very large well for irrigation. Most domestic wells have 15 centimetre casing.

    Figure \(\PageIndex{2}\) Three wells in an unconfined aquifer. Well A is not being pumped. Well B is being pumped at a slow rate and well C, which has a larger cone of depression, is being pumped at a faster rate.

    Pumping water from the well removes water from inside the well at first. That lowers the water level inside the well. This means that water will flow from the surrounding aquifer toward the pumping well where the water level is now lower.

    Figure \(\PageIndex{3}\) A similar scenario to that in Figure \(\PageIndex{2}\), but in this case, well C has been pumped unsustainably for a long time. The cone of depression from well C has reached well B and has contributed to it going dry because the water level is now below the bottom of well B.

    That is how a well gets water from the ground. The water table, or potentiometric surface, will slope in toward the well where the water is being withdrawn. That indicates the energy gradient that is allowing water to flow toward the well. This creates a shape known as a cone of depression surrounding the well, as illustrated in Figure \(\PageIndex{2}\). If pumping from a well continues for hours to days, the cone of depression may result in a loss of water in nearby wells. As shown in Figure \(\PageIndex{3}\), pumping of well C has contributed to well B going dry because the water level is now below the bottom of well B. If pumping continues in well C, it too may go dry.

    Exercise 14.2 Cone of depression
    After long-term pumping, a cone of depression has formed at this well.
    Figure \(\PageIndex{4}\)

    The two diagrams here show the same well before (left) and after (right) long-term pumping. A cone of depression has developed. This provides the energy gradient for water to flow toward the well so that it can be pumped out.

    How will this likely affect the rate of flow into the well?

    See Appendix 3 for Exercise 14.2 answers.

    Like other provinces in Canada and states in the US, British Columbia has a network of observation wells administered by the Ministry of the Environment. These are wells that are installed to measure water levels; they are not pumped. There are 145 active observation wells in B.C. (in 2015), most equipped with automatic recorders that monitor water levels continuously. The main purpose of the observation wells is to monitor water table levels so that we can see if there are long-term natural fluctuations in groundwater quantity, and shorter-term fluctuations related to overuse of the resource. Most are also sampled regularly to monitor groundwater chemistry and quality.

    An example of an observation well is illustrated in Figure \(\PageIndex{5}\). This one is situated at Cassidy on Vancouver Island and is used to monitor an unconsolidated aquifer that is widely used by residents with private wells.

    Figure \(\PageIndex{5}\) B.C. observation well 228 near Cassidy, Vancouver Island. The installation also has a solar panel, which is not visible in this view.

    The water-level data from B.C.’s observation wells are available to the public, and an example data set is illustrated in Figure \(\PageIndex{6}\). The water level in Ministry of Environment observation well 232 (OW-232), situated in Lantzville on Vancouver Island, dropped significantly from 1979 (average depth around 1.5 meters), to 2003 (average depth around 5.5 meters), but has recovered a little since then.

    Figure \(\PageIndex{6}\) Water level data for B.C. observation well 232 on Harby Rd., Lantzville, Vancouver Island. From 1979 to 2003, depths were recorded monthly. Automated equipment was installed in 2003, and the depths were recorded hourly since that time.

    The short-term variations in the level of well 232 are at a period of one year and are related to annual cycles of recharge and discharge governed by the wet winter climate and drier summers. The data for part of the period are shown in more detail in Figure \(\PageIndex{7}\). In most of British Columbia most wells drop to their lowest levels in September or October after the relatively dry summer period. Levels increase rapidly from October through February as high winter precipitation adds recharge to the aquifer, and water is stored. The water table reaches a peak in March or April. Most wells then drop over the summer as groundwater continues to flow, but no new recharge is added. The water is drained from storage into streams or lakes and eventually into the ocean, and as a result, the water table decreases, reaching its lowest level again in September or October. Similar fluctuations are observed at most observation wells around the province, although the timing is slightly different from region to region.

    Figure \(\PageIndex{7}\) Water level data for B.C. observation well 232 for the period 1996 to 2000, showing seasonal variations.

    The long-term fluctuations in levels in observation wells in different places are also quite variable. Long-term changes in climate can lead to gradual natural changes in water levels. These long-term cycles lasting years or decades are mixed with the effects of well pumping. Some observation wells show consistent decreases in water level that may indicate long-term over-extraction. Many others show generally consistent levels over several decades, and some show increases in water level. One of the important jobs performed by hydrogeologists working for government agencies is to examine these long-term records of water levels for indications of how sustainable the groundwater use might be.

    Exercise 14.3 What’s your water table doing?

    Visit the B.C. Ministry of the Environment observation well website and use the map to find an observation well near you. When you click on a point, a window pops up with a link that says, “Click for details about this well.” Click on that link and then choose one of the options available. The “Graphs” tab will show you a graph of the water levels, and you should be able to tell if the level is generally increasing or decreasing. If there isn’t much data to see, choose a different well.

    (Similar data are available for Alberta and Saskatchewan and other jurisdictions as well. Search using terms like “Alberta observation wells.”)

    See Appendix 3 for Exercise 14.3 answers.

    In 2016 the new Water Sustainability Act came into effect in British Columbia, requiring licensing groundwater extraction for the first time. The new Act also includes provisions for determining “environmental flow needs”—the amount of water that must be in surface water streams at different times of the year to meet the needs of the ecosystem that depends on the streamflow. For example, many streams in B.C. support populations of salmon that live in the stream for part of their life cycle or return to their home stream for spawning. Groundwater forms a part of the baseflow in a watershed, and is therefore an important part of the environmental flow needs. Careful work is needed in the coming years to ensure that the amount of water licensed to be extracted from surface water and groundwater for human use does not interfere with the amount of water needed for the natural water-dependent ecosystems to function.

    Figure \(\PageIndex{8}\) Changes in water levels in wells in California from 2011 to 2013.

    The situation in California, where groundwater extraction over large areas is leading to declining water levels, is quite different from that in B.C. According to the state Department of Water Resources, 80% of groundwater wells showed drops in water level of 0 meters to 7.5 meters between 2011 and 2013, another 6% dropped by 7.5 meters to 15 meters, and 3% dropped by more than 15 meters (Figure \(\PageIndex{8}\)). Over the same time period, only 10% of well levels increased by 0 meters to 7.5 meters, and 1% increased by more than 7.5 meters. The drought that gripped California in 2013 had worsened significantly by 2015, and California farmers — and the people across North America that eat the food they produce — continue to have a prodigious appetite for irrigation water. California, like B.C., is introducing new groundwater regulations to try to control water usage and halt water table declines.

    Impermeable Surfaces

    Even if groundwater supplies are not being depleted by overuse, or by a changing climate, we are continuing to put stress on aquifers by covering vast areas with impermeable surfaces that don’t allow rain and snow-melt to infiltrate and become groundwater. Instead, water that falls on these surfaces is channeled into drainage systems, then into storm sewers, and then directly into rivers and the ocean. In cities and their suburbs, the biggest culprits are parking lots, roads, and highways. While it would great if we didn’t dedicate such huge areas to cars, that’s not about to change quickly, so we need to think about ways that we can improve surface water infiltration in cities. One way is to use road and parking surfaces that will allow water to seep through, although this is not practical in many cases. Another way is to ensure that runoff from pavement is channeled into existing or constructed wetlands that serve to decontaminate the water, and then allow it to infiltrate into the ground.

    Image Descriptions

    Figure \(\PageIndex{5}\) image description: Inside a box attached to the well casing, there is a battery, a depth sensor wheel, a spare float, and an instrument that provides a depth readout. This one says 4.047 meters. There is also a communication antenna. [Return to Figure \(\PageIndex{5}\)]

    Media Attributions

    • Figure \(\PageIndex{1}\), 14.3.2, 14.3.3, 14.3.4, 14.3.5: © Steven Earle. CC BY.
    • Figure \(\PageIndex{6}\): © Steven Earle. CC BY. Based on data from “Observation Well #232.
    • Figure \(\PageIndex{7}\): © Steven Earle. CC BY. Based on data from “Observation Well #232.”
    • Figure \(\PageIndex{8}\):© Steven Earle. CC BY. Based on State of California Department of Water Resources data.

    This page titled 14.3: Groundwater Extraction is shared under a CC BY 4.0 license and was authored, remixed, and/or curated by Steven Earle (BCCampus) via source content that was edited to the style and standards of the LibreTexts platform; a detailed edit history is available upon request.

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