No Water, No Power

Via the World Resources Institute, an article on the watergy nexus:

Drought in Kenya and neighboring countries became so severe earlier this year that the government of Kenya declared a national disaster. Already, the effects have been devastating: Food production dropped, leaving more than 2.6 million people without access to sufficient food. Some villagers have lost 40 percent of their livestock. But the disaster also affects the power sector.

Amidst the human tragedy of this drought, an unexpected actor faced shutdowns and economic losses due to water scarcity: the power sector. Almost 70 percent of Kenya’s electricity is generated by two water-dependent sources: hydropower and fossil fuels. According to Business Daily, the drought has caused Kenya’s reserve energy margin—the amount of energy needed to meet peak demands— to drop to 4.4 percent, far lower than the recommended 15 percent needed to minimize risk of blackouts.

Kenya isn’t the only country whose electricity supplies have been impacted by scarce water: In 2016 India’s coal power sector—which is highly dependent on water for cooling—suffered profit losses of, at minimum, $350 million due to severe drought.

As energy demand from industrial and domestic uses increases and water availability decreases, the energy industry in Kenya, India and other water-stressed locations around the world face increased business risks.

The Water-Energy Connection

Hydropower and thermoelectric power make up 98 percent of the world’s electricity generation. These two most common forms of power are also the most water-intensive, which makes them extremely vulnerable to drought, competition over water resources and other water shortages.

Hydropower’s dependency on ample water resources is clear. Dams convert falling water—mechanical energy— into electrical energy. Without water, there is no energy source to convert. Such is the case during Kenya’s drought.

The water intensity of thermal power plants, however, is not immediately obvious. Thermal power plants use fuel to create heat, which is then converted to electrical energy. These plants whether fueled by coal, natural gas, nuclear energy or even solar thermal electric energy—often require water to cool down plants’ high temperatures. A water shortage—or water with too high of a temperature—can impede this process.

Water is also integral to a plant’s core functioning, since heating water into steam powers the turbines of most thermal power plants. Many thermal power plants are located next to bodies of water, so that they can easily withdraw what they need. When water supply is interrupted, a plant could suffer generation disruptions, or even shut down completely.

A Global Problem

In 2016, the World Energy Council warned, “we will start to see the effects of water scarcity on energy supplies in the very near future.” The effects are already starting to show, as evidenced by Kenya and India’s droughts and subsequent power plant curtailments. This issue is not unique to one country or continent; power plants from Asia to Europe to Africa to the Americas are suffering due to water scarcity.

Some examples:

  • In 2010, Hoover Dam’s generating capacity was reduced by 23 percent due to falling water levels. This has become a persistent problem during dry times– the dam’s capacity was reduced 30 percent in 2016, due to drought.
  • In 2011, a Romanian state-owned hydropower producer Hidroelectrica cut production by 30 percent due to depleted reservoirs caused by a prolonged drought.
  • In 2011, an extreme drought hit Yunnan, a province in Southwest China. This caused Yunnan’s hydropower output to drop by half, and forced over 1,000 dams to suspend operations.
  • In 2016, Ghana’s main source of energy, the Akosombo Dam, operated at minimum capacity due to drought.
  • In 2016, drought hit Brazil, affecting hydroelectric power producers such as the Itaipu Dam. This forced the country to turn to more expensive and more polluting thermoelectric plants.

Growing Energy Demand, Growing Water Stress

The International Energy Agency’s World Energy Outlook 2016 found that energy production currently accounts for 10 percent of the world’s total water withdrawals – most of which is used in power plant operations. If current trends continue, hydro and thermal power’s thirst for water will increase even more. This would result in even higher water withdrawals and water consumption (due to water that is withdrawn and lost to evaporation during the thermal power process).

The more the energy sector depends on water, the more it exposes itself to vulnerabilities. At the same time, climate change is bringing warmer temperatures, increased variability, and increased water scarcity in mid-latitude zones —all which negatively impact the electric power industry. The more the climate warms, the more the power sector will suffer: Experts predict that power production in European thermal plants could drop by 19 percent between 2031 and 2060 due to shut-downs impacted by climate change.

In places projected to face both higher temperature and lower precipitation—such as South America and parts of southern Africa—energy generation will feel the pain of climate change to an even further degree. There is a troubling overlap between water-stressed areas and those that need energy the most: In sub-Saharan Africa, which includes dry areas like drought-stricken Kenya, seven out of ten people lack access to electricity. If thirsty forms of energy are used in these areas, shutdowns due to water shortages may ensue.

It’s important that power plants in vulnerable regions act early by developing climate adaptation strategies and investing in technologies that can save water (such as dry cooling and wastewater recycling) to reduce potential water-related risks. Beyond power plants and dams, renewable energy technologies such as solar photovoltaic cells and wind energy are less dependent on water. In China, WRI is using our Baseline Water Stress: China tool to map intersections of water stress and thermal power generation across the country. In addition, we’re measuring the competition for water between the power sector and other sectors – such as agricultural and domestic users. With more information about where and when power plants compete for water with other thirsty sectors, policy makers can make informed decisions about the tradeoffs of switching to less water-intensive options for energy production in the future.

This entry was posted on Tuesday, July 4th, 2017 at 7:24 am and is filed under Uncategorized.  You can follow any responses to this entry through the RSS 2.0 feed.  You can leave a response, or trackback from your own site. 

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About This Blog And Its Author
As the scarcity of water and energy continues to grow, the linkage between these two critical resources will become more defined and even more acute in the months ahead.  This blog is committed to analyzing and referencing articles, reports, and interviews that can help unlock the nascent, complex and expanding linkages between water and energy -- The Watergy Nexus -- and will endeavor to provide a central clearinghouse for insightful articles and comments for all to consider.

Educated at Yale University (Bachelor of Arts - History) and Harvard (Master in Public Policy - International Development), Monty Simus has held a lifelong interest in environmental and conservation issues, primarily as they relate to freshwater scarcity, renewable energy, and national park policy.  Working from a water-scarce base in Las Vegas with his wife and son, he is the founder of Water Politics, an organization dedicated to the identification and analysis of geopolitical water issues arising from the world’s growing and vast water deficits, and is also a co-founder of SmartMarkets, an eco-preneurial venture that applies web 2.0 technology and online social networking innovations to motivate energy & water conservation.  He previously worked for an independent power producer in Central Asia; co-authored an article appearing in the Summer 2010 issue of the Tulane Environmental Law Journal, titled: “The Water Ethic: The Inexorable Birth Of A Certain Alienable Right”; and authored an article appearing in the inaugural issue of Johns Hopkins University's Global Water Magazine in July 2010 titled: “H2Own: The Water Ethic and an Equitable Market for the Exchange of Individual Water Efficiency Credits.”