# Lens (hydrology)

A freshwater lens on an island.

In hydrology, a lens, also called freshwater lens or Ghyben-Herzberg lens, is a convex-shaped layer of fresh groundwater that floats above the denser saltwater, usually found on small coral or limestone islands and atolls. This aquifer of fresh water is recharged through precipitation that infiltrates the top layer of soil and percolates downwards until it reaches the saturated zone. The recharge rate of the lens can be summarized by the following equation:

R = P − ET

Where R is the recharge rate in meters, p is precipitation (m), and ET is evapotranspiration (m) of water. With higher amounts of recharge, the hydraulic head is increased and a thick freshwater lens is maintained through the dry season. Lower rates of precipitation or higher rates of interception and evapotranspiration will decrease the hydraulic head resulting in a thin lens.[1]

## Models of freshwater lenses

### Algebraic model

An algebraic model for estimating the thickness of a freshwater lens was developed using groundwater simulations by Bailey et al. 2008. This equation relates lens thickness to geologic and climatic factors such as island geometry, geologic composition, and recharge rate, among others.[1] The equation is summarized below:

${\displaystyle Z_{max}={\frac {Y+(Z_{td}-Y)R}{B+R}}\cdot KCT_{r,s,w,y,m}}$

Where ${\displaystyle Z_{max}}$  = maximum depth of the lens, ${\displaystyle R}$  = annual recharge rate ${\displaystyle (m)}$ , ${\displaystyle Y}$  and ${\displaystyle B}$  = parameters depending on the width of the island, ${\displaystyle Z_{td}}$  = depth to Thurber Discontinuity (the transition between the upper and lower aquifers), ${\displaystyle K}$  = hydraulic conductivity of the upper aquifer, ${\displaystyle C}$  = confining reef plate parameter, and ${\displaystyle T}$  = time parameter depicting long-term rainfall patterns with the subscripts representing different aspects of this such as region, weather pattern, etc.

Many freshwater aquifers on atolls and small rounded islands take on the form of a Badon Ghyben-Herzberg Lens.[2] This relationship is described in the equation below:

${\displaystyle H=h\cdot {\frac {P_{f}}{P_{s}-P_{f}}}}$

Where H = the depth of the lens below sea level, ${\displaystyle P_{f}}$  = the density of the freshwater aquifer, ${\displaystyle P_{s}}$ = density of saltwater, and ${\displaystyle h}$  = thickness of lens above sea level.

## Effects of drought

Freshwater lenses rely on seasonal rainfall to recharge the underground aquifer and can drastically change in thickness following drought or heavy rainfall. A USGS report following the 1997/1998 drought in the Marshall Islands observed a noticeable decline in the thickness of the lens.[3] After the reservoirs of the public rainfall catchment system were rapidly depleted following several months of inadequate precipitation, the islands' population began increasing the rate of groundwater pumping to the point that groundwater supplied up to 90% of the island's drinking water during the drought.

A network of 36 monitoring wells at 11 sites was installed around the island to measure the amount of water depleted from the aquifer. By the end of the drought in June 1998, the maximum thickness of the freshwater lens was about 45 feet in some wells, while one site measured a thickness as low as 18 feet. Following the resumption of the rainy season, the thickness of the lens increased by up to 8 feet in some areas, indicating that the recharge rate of freshwater lenses on atolls and small islands responds rapidly to changes in precipitation and groundwater pumping rate.

## Effects of sea level rise

Many of the atolls that support freshwater lenses are only a few meters above sea level and as such they are at risk of inundation due to sea level rise. However, an arguably more pressing issue facing these small islands is the intrusion of saltwater on the freshwater aquifer. As more and more of the potable groundwater is salinized, the populations of these islands may see a substantial reduction in available water resources. Smaller islands are at a far greater risk of extensive saltwater intrusion due to a non-linear relationship between island width and thickness of the freshwater lens.[4]

A 40 cm rise in sea level can have a drastic effect on the shape and thickness of the freshwater lens, reducing its size by up to 50% and encouraging the formation of brackish zones. Saline plumes can form at the bottom of the freshwater aquifer when the lens thickness is compromised by drought and saltwater intrusion. Even after a full year of groundwater recharge, the saline plume may not completely dissipate. Sea level rise will likely lead to sustained and possibly irreparable damage to freshwater lenses due to an increase in cyclone-generated wave washover, rendering many islands uninhabitable with the loss of potable water.[5]

## References

1. ^ a b Bailey, Ryan T., John W. Jenson, and Arne E. Olsen. An atoll freshwater lens algebraic model for groundwater management in the Caroline Islands. Water and Environmental Research Institute of the Western Pacific, University of Guam, 2008. http://www.weriguam.org/docs/reports/120.pdf
2. ^ MCLANE, Charles. "Effect of withdrawals from a simulated island freshwater lens aquifer system: an analytic element modeling approach." McClane Environmental, LLC. 2002 Denver Annual Meeting. 2002. http://us1media.com/PresGalleries/presdownloads/island_freshwater_lens.pdf
3. ^ Presley, Todd K. Effects of the 1998 drought on the freshwater lens in the Laura area, Majuro Atoll, Republic of the Marshall Islands. No. 2005-5098. Geological Survey (US), 2005. https://pubs.usgs.gov/sir/2005/5098/pdf/sir20055098.pdf
4. ^ Chui, Ting Fong May, and James P. Terry. "Influence of sea-level rise on freshwater lenses of different atoll island sizes and lens resilience to storm-induced salinization." Journal of hydrology 502 (2013): 18–26.
5. ^ Terry, James P., and Ting Fong May Chui. "Evaluating the fate of freshwater lenses on atoll islands after eustatic sea-level rise and cyclone-driven inundation: a modelling approach." Global and Planetary Change 88 (2012): 76–84.