Dams & Global Warming

You will probably be hearing scare reports about this soon, but not to worry, dams only produce 1.5 % of human caused global warming, according to this article from Reflections on Water.

An excerpt.

Last month, global atmospheric carbon dioxide concentrations reached 400 ppm signaling that greenhouse gases are continuing to rise and the momentum of global climate change is well underway.  Carbon dioxide is only one of several greenhouse gasses – where methane is the most potent of all and 30 times stronger than carbon dioxide.  Most attention on methane emissions has been on that coming from burping corn-fed cows or leaks from fracking to produce natural gas.  The notorious methane leak in Aliso Canyon by Southern California Gas Company during fracking didn’t go under anyone’s radar, since it resulted in a leak in 100,000 tons of methane gas – said to be equivalent to annual emissions from half a million cars.  However, a new study published in Bioscience this past week has highlighted a new source of methane that was previously unaccounted for in global estimates – Dams.  The study found dams emit 25% more methane than we previously thought. Meaning dams are contributing approximately 1.5% of global anthropogenic greenhouse gas emissions. Making a strong case that greenhouse gas emissions from dams be included in IPCC budgets and other global inventories, when previously they have not been.

How are dam reservoirs any different from lakes?

Methane release from both man-made reservoirs and lakes originate from the sediments beneath the water. The root cause of methane release is the decay of dead organic matter in these sediments that originated from leaves, trees, algae, and fish that sunk from the waters above.  As you can imagine, the amount of oxygen present in the sediments under these waters can be quite low, causing bacteria eating this dead organic matter to depend on other molecules containing oxygen.  These include nitrate, phosphate, sulfate, and carbon dioxide. The least appealing molecule to breathe for these microbes is carbon dioxide because it requires the greatest energy to break the molecule apart to access the oxygen.  When these microbes have no choice than to breathe carbon dioxide, a process called “methanogenesis” occurs.  This means that for every carbon dioxide molecule that is consumed, one molecule of methane is exhaled.  When methane gas starts to accumulate in the sediments, it will bubble up, float to the surface of the water, and rise into our atmosphere.

There are three main differences between man-made reservoirs and lakes: 1.    Man-made reservoirs require flooding terrestrial land, supplying a large pulse of dead organic matter from trees and grasslands.  The timescale of how this happens to natural lakes is much longer. 2.    Man-made reservoirs experience greater fluctuations than natural lakes. As reservoirs reduce in volume, the weight of the water over the sediments drop freeing even more methane molecules from the confines of their origin. 3.    Man-made reservoirs are often closer to human activities, such as agricultural run-off containing fertilizers that can promote the growth of organic matter in the water.

What are the alternatives?

So, it seems as though hydropower is not as clean as we once thought.  But that’s isn’t a good reason to be ripping out dams.  Hydropower generation often replaces much dirtier sources of energy, such as coal and even natural gas.  In addition, dams provide us wide range of public benefits such as flood control, recreation, and water management.  It is important to note, however, that if a plans for a new dam are not going to provide hydroelectric supply and only provide water storage – groundwater storage may be a ‘cleaner’ alternative.  Groundwater recharge basins are regularly maintained to have less organic matter at the bottom, since it can clog the percolation of water into groundwater aquifers beneath.  In addition, recharge basins are shallower than man-made reservoirs and periodically become empty during dry periods when less water is available to recharge groundwater.  This periodic drying out helps keep soils aerated, whereas man-made reservoirs can stay inundated with water for longer periods of time.

About David H Lukenbill

I am a native of Sacramento, as are my wife and daughter. I am a consultant to nonprofit organizations, and have a Bachelor of Science degree in Organizational Behavior and a Master of Public Administration degree, both from the University of San Francisco. We live along the American River with two cats and all the wild critters we can feed. I am the founding president of the American River Parkway Preservation Society and currently serve as the CFO and Senior Policy Director. I also volunteer as the President of The Lampstand Foundation, a nonprofit organization I founded in 2003.
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