Peak water

Peak water is a concept that underlines the growing constraints on the availability, quality, and use of freshwater resources. Peak water was defined in 2010 by Peter Gleick and Meena Palaniappan. They distinguish between peak renewable, peak non-renewable, and peak ecological water to demonstrate the fact that although there is a vast amount of water on the planet, sustainably managed water is becoming scarce. Lester R. Brown, president of the Earth Policy Institute, wrote in 2013 that although there was extensive literature on peak oil, it was peak water that is "the real threat to our future". An assessment was published in August 2011 in the Stockholm International Water Institute's journal. Much of the world's water in underground aquifers and in lakes can be depleted and thus resembles a finite resource. The phrase peak water sparks debates similar to those about peak oil. In 2010, New York Times chose "peak water" as one of its 33 "Words of the Year". There are concerns about impending peak water in several areas around the world: Peak ecological water, where ecological and environmental constraints are overwhelming the economic benefits provided by water use Peak non-renewable water, where groundwater aquifers are being overpumped (or contaminated) faster than nature recharges them (this example is most like the peak oil debate) Peak renewable water, where entire renewable flows are being consumed for human use If present trends continue, 1.8 billion people will be living with absolute water scarcity by 2025, and two-thirds of the world could be subject to water stress. Ultimately, peak water is not about running out of freshwater, but about reaching physical, economic, and environmental limits on meeting human demands for water and the subsequent decline of water availability and use. The Hubbert curve has become popular in the scientific community for predicting the depletion of various natural resources. M. King Hubbert created this measurement device in 1956 for a variety of finite resources such as coal, oil, natural gas and uranium.

A ‘common garden’ to understand and predict effects of glacier shrinkage of microbial life in high-mountain streams

Domestic hot water optimizing potential in existing or renovated multifamily residential buildings

Temperature of artificial freshwater recharge significantly affects salinity distributions in coastal confined aquifers

Temperature of artificial freshwater recharge significantly affects salinity distributions in coastal confined aquifers

A ‘common garden’ to understand and predict effects of glacier shrinkage of microbial life in high-mountain streams

Domestic hot water optimizing potential in existing or renovated multifamily residential buildings