In our series so far, we have heard mostly from people in the bottled beverage business, talking about opportunities to become more sustainable by improving their packaging and by using water more efficiently. This, of course, is only one facet of the future of drinking water and we will be exploring several others as the series continues. But at this point I wanted to stop and reflect on the question of water efficiency. It’s great to see beverages companies taking pains to use less water. But how do we, or for that matter, how do they know when they have gone far enough?
We’ve all heard that water availability is and will continue to be a major issue and unlike oil, where we can look at the price per barrel or the price at the gas pump, or global warming, where we can keep track of the ppm of CO2 in the atmosphere relative to a stated goal (e.g. 350), there is no clear reference point.
I asked Peter Gleick, President of the Pacific Institute and author of Bottled and Sold, The Story Behind Our Obsession With Bottled Water about this and he sent me an article of his that had been published in the Proceedings of the National Academy of Science entitled, “Peak water limits to freshwater withdrawal and use.”
As we all know, our planet is mostly water. So the idea of us ever running out of it, especially considering that most of what we use is naturally recycled, seems absurd.
Just for reference, the planet contains roughly 1.4 billion cubic kilometers of water. About 97.5% of that is contained in the oceans or in saline groundwater. Of the remaining 2.5%, a little more than two-thirds are contained in glaciers. That leaves some 10.5 million cubic kilometers. Estimates of human water withdrawals in the early 2000s ran around 3700 cubic kilometers, which is somewhere in the neighborhood of one three-thousandth of the total. So, it sounds like there is no problem.
There is a problem, however, because water, like money, is not distributed equally. As Michael Moore pointed out in his recent essay, where he says that America is not broke; it’s just that the same amount of money is now in fewer pockets; the same is basically true with water, too. While some areas are having terrible droughts, others are experiencing floods which are not particularly helpful, either. For this reasons, it is really only meaningful to talk about peak water on a regional basis.
Gleick describes three types of peak water: peak renewable water, peak ecological water and peak non-renewable water. Renewable water is water that is replenished though snow melt or rainfall. As such, it is flow limited. It reaches a peak when the level withdrawn meets or exceeds the level of replenishment. Renewable is not the same as unlimited. Non-renewable water is like oil. It is found in “fossil” aquifers that are not being replenished at meaningful rates. It is stock-limited. In this sense it is like peak oil, which occurs when the rate of production begins to decline. Peak ecological water refers the amount of water that can be withdrawn from a river, stream or lake, before the damage and disruption costs more than the value of the water withdrawn.
Many factors complicate the analysis of water as a resource, including the renewable and non-renewable sources, consumptive and non-consumptive uses, as well as fresh vs. salt water, which can also be made interchangeable with the addition of sufficient energy, a resource that has its own scarcity issues.
The bottom line here is water availability. Even in the case of renewable sources, if water is evaporated by a cooling tower or diverted to a treatment plant, it will eventually return to a usable state, but in the meantime, it is unavailable.
A number of river basins have already reached their ecological peak including the Colorado, which no longer reaches the Pacific, as well at the Yellow River, the Nile and the Jordan. These areas have all seen substantial ecological impacts. Nonrenewable water sources that are approaching and may have reached their peak production include: the Ogallala Aquifer, the North China Plains, California’s Central Valley and numerous basins in India that account for roughly 8% of that country’s water use.
So while we have not yet reached the point where we have a “gas gauge” for water consumption, we do have an ever-growing understanding of the issues and the critical factors. I reviewed an interesting book on this subject last year, Running Out of Water by Peter Rogers and Susan Leal. Another book on the subject entitled Peak Water, by Alexander Bell, is reviewed here.
RP Siegel is the co-author of the eco-thriller Vapor Trails the first of a series dealing with the human side of energy, food and water. Like airplanes, we all leave behind a vapor trail. And though we can easily see others’, we rarely see our own.
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RP Siegel, author and inventor, shines a powerful light on numerous environmental and technological topics. His work has appeared in Triple Pundit, GreenBiz, Justmeans, CSRWire, Sustainable Brands, Grist, Strategy+Business, Mechanical Engineering, Design News, PolicyInnovations, Social Earth, Environmental Science, 3BL Media, ThomasNet, Huffington Post, Eniday, and engineering.com among others . He is the co-author, with Roger Saillant, of Vapor Trails, an adventure novel that shows climate change from a human perspective. RP is a professional engineer - a prolific inventor with 53 patents and President of Rain Mountain LLC a an independent product development group. RP was the winner of the 2015 Abu Dhabi Sustainability Week blogging competition. Contact: firstname.lastname@example.org