Scientists and engineers, including Greg Characklis at the University of North Carolina at Chapel Hill, are studying the connections between water, food and energy in the human water cycle to develop new, sustainable ways of meeting our water needs. "Human Water Cycle" is produced by NBC Learn in partnership with the National Science Foundation.
Human Water Cycle -- Water, Food and Energy
ANNE THOMPSON reporting:
Water. It is an essential building block of life constantly moving in a hydrologic cycle that flows in a continuous loop above, across and even below the Earth's surface. But water is also constantly moving through another cycle, the human water cycle, which powers our homes, hydrates our bodies, irrigates our crops, and processes our waste. The tight connection between water, food and energy also makes them dependent on one another. Our increasing need for these three vital resources is forcing us to rethink how we manage and use our water supply.
GREG CHARACKLIS (UNC AT CHAPEL HILL): Water is a challenge because there's so much uncertainty. The hydrologic cycle is highly variable. Societies come to depend on a reliable supply of water in almost everything that we do. So if that's disrupted in any way, there are big social and economic consequences.
THOMPSON: With funding from the National Science Foundation, scientists and engineers, such as Greg Characklis at the University of North Carolina at Chapel Hill, are researching new, sustainable ways to meet our water needs, studying each connection in the human water cycle to gain more knowledge about the interconnections among water, food and energy.
CHARACKLIS: If we have an understanding of all of those factors, we can put together the types of rules and the types of what we call management systems that will allow people to make better decisions.
THOMPSON: The water needed to produce our food and energy typically comes from freshwater sources, such as rivers, lakes and underground aquifers. In order to make it safe for drinking, most water must be transported through a water treatment plant to remove contaminants, or in the case of salty water, through a desalination process. Orlando Coronell at the University of North Carolina at Chapel Hill is improving water purification technology called high-pressure membranes, which are able to remove contaminants as small as one thousandth the diameter of a single strand of human hair.
ORLANDO CORONELL (UNC AT CHAPEL HILL): We as humans need water for our daily survival. Most of our body is made up of water, and as a result, we need to consume it every day. High-pressure membranes are a great technology. We use it to remove these very small contaminants and all sorts of contaminants from the water.
THOMPSON: Contaminants such as bacteria, parasites, and viruses that could affect public health. What happens to the water we flush down the toilet or rinse down the sink? It is transported to a wastewater treatment plant to remove organic carbon and nutrients, such as nitrogen and phosphorus, before it can be safely released back into the environment. Kartik Chandran at Columbia University in New York City is researching new ways of recovering those nutrients from wastewater to produce energy.
KARTIK CHANDRAN (COLUMBIA UNIVERSITY): Instead of calling this wastewater, to me, this is enriched water. We have been able to convert the organic carbon and food waste, in sewage sludge, in fecal sludge, to biodiesel, which is a liquid fuel easily transported and easily used, directly used in diesel engines.
THOMPSON: Water can be diverted to produce hydropower, the largestsource of clean electric energy in the United States. Yet water is essential in other forms of energy production too, such as coal, gas and nuclear power.
CHARACKLIS: It's brought into the plant, it's used to cool, and then the warmer water then is redelivered back into the stream.
THOMPSON: Our food supply is reliant on water. In dry regions such as the California Central Valley, the Texas Panhandle or the High Plains of Kansas, irrigation, or the delivery of water to crops artificially, is vital to the success of a farmer's crop yields. Without the additional water to supplement natural rainfall, fields would go dry and food production would plummet. Irrigation often leads to something called soil salinization, an excess of salt leftover after water evaporates or transpires, preventing plants from taking in water and nutrients. Meagan Mauter at Carnegie Mellon University is working to improve desalination methods and soil salinity data collection to help farmers make better water management decisions for the future.
MEGAN MAUTER (CARNEGIE MELLON UNIVERSITY): In the past, we've been entirely dependent on a manual sampling of soils around the country, and while that's effective, it's both cost intensive and labor intensive. If we can predict the soil salinity using satellite data, we could both get higher resolution measurements of soil salinity throughout the United States, but we could also scale this up to global areas, where we believe that soil salinization is a concern.
THOMPSON: While there are many challenges placed on our water, food, and energy security, scientists and engineers are asking questions and working toward solutions that will benefit us all.
CHARACKLIS: How do we manage the water that we've got? Do we build more reservoirs? Do we develop more efficient technologies? These are all questions that come into play when we try to think about how are we going to ensure reliable water supply well into the future.
THOMPSON: Two water cycles, one natural, one human-made, yet both are fundamental to meet our growing needs for water, food and energy.
Viewed from space, one of the most striking features of our home planet is the water, in both liquid and frozen forms, that covers approximately 75 percent of the Earth’s surface. Geologic evidence suggests that large amounts of water have likely flowed on Earth for the past 3.8 billion years — most of its existence.
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