Two years after its historic deep freeze, Texas is increasingly vulnerable to cold snaps—and there are more solutions than just building power plants

    In our view, an approach that employs every tool in the toolbox—including efficiency, demand response and increased grid connectivity—would better serve the state.

    SOURCEThe Conversation

    Texans like to think of their state as the energy capital of the world. But in mid-February 2021, the energy state ran short of energy.

    An intense winter weather outbreak, informally dubbed Winter Storm Uri by the Weather Channel, swept across the U.S., bringing snow, sleet, freezing rain and frigid temperatures. Texas was hit especially hard, with all 254 counties under a winter storm warning at the same time.

    Across the state, sustained arctic temperatures froze power plants and fuel supplies, while energy demand for home heating climbed to all-time highs. Cascading failures in the electric power and natural gas sectors left millions of people in the dark for days. At least 246 people died, possibly many more, and economic damage estimates damages reached US$130 billion.

    Water systems, which require energy for pumping and treatment, also were severely damaged. At least 10 million people were under boil-water notices during and after the storm, sometimes for weeks. Low-income and minority residents, who had fewer resources to find alternative housing and make repairs, suffered the worst impacts.

    As energy researchers based in Texas, we have spent much of the past two years analyzing why the state was so unprepared for this event and how it can do better. A common knee-jerk reaction to disasters that cause widespread power outages is to call for building more “firm” power plants—those that use fuels like coal or natural gas and are designed to deliver power at any time of day or night. But coal and gas plants, and their fuel supplies, can fail spectacularly.

    We think it is important to think beyond just building more power plants. Our findings spotlight other solutions that can be cleaner, cheaper and faster to put in place.

    Planning for winter

    Analyses after Uri revealed that a lack of winterization in the electric and gas sectors was a critical cause of system-wide failure. The Texas legislature enacted new winterization requirements for electricity generators. But it did not do the same for natural gas producers, which provide fuel to about 40% of Texas power plants and weren’t able to deliver during the storm.

    Since then, Texas saw significant drops in natural gas production during winter cold snaps in January and February 2022. As happened during Uri, production at many gas wells was halted because water and other liquids that come to the surface with the natural gas froze when they hit a frozen wellhead, creating an ice dam and stopping the flow of gas into pipelines.

    In December 2022, Winter Storm Elliott caused more drops in gas production, as well as power outages across the Southeast U.S. These events show that winter reliability risks are not specific to Texas.

    Cold weather challenges

    Our research shows that winter peak electricity demand in Texas – driven by electric space heating – has become more sensitive to cold temperatures over the past 20 years. Winter peaks are also growing faster and are more erratic than summer peaks. We know that every summer is going to be hot, but we don’t know for certain that winter will be cold, which makes it harder to plan.

    Texas is at the forefront of a national shift to heating homes with electricity instead of oil or gas. About 60% of homes in Texas use either heat pumps or electric resistance heating.

    Heat pumps shift home winter energy demand from carbon-emitting sources like natural gas to electricity. They can also cool buildings more efficiently than older air conditioning units. However, heat pumps that aren’t rated for low temperatures can use more energy to heat in the winter than to cool in the summer. Better minimum efficiency standards can help mitigate this challenge.

    The shift to electricity for heating indicates that within the next few decades, electricity demand in Texas is likely to regularly peak in winter rather than summer. Meanwhile, lower-demand shoulder seasons in spring and fall—the times when fossil fuel and nuclear power plants normally go offline for maintenance—are getting shorter, as heat waves start earlier and winter storms push later into the spring.

    What do we do now?

    These trends are making it harder for grid planners and operators to ensure sufficient power capacity is always available, especially in winter. In addition to making sure Texas has enough generating capacity online, here are three areas where we believe the state should do more:

    – Promote energy efficiency.

    Currently the nonprofit American Council for an Energy-Efficient Economy ranks Texas 29th among the states for its policies and programs to save energy and promote energy efficiency. Adopting policies such as stricter building codes and minimum appliance efficiency standards would reduce consumers’ energy bills. It also would lower peak demand during extreme events. And if outages still occur, well-insulated houses will stay warm or cool for longer, reducing risks to occupants.

    – Increase investment in demand response.

    Demand response programs offer electricity customers incentives to turn off noncritical appliances, like pool pumps or water heaters, for short periods to reduce overall load on the grid during periods of high demand. For real-time balancing of supply and demand on the grid, turning off 500 megawatts of noncritical demand is functionally equivalent to turning on a 500-megawatt power plant. While Texas has made some progress in this area, it is below average relative to its peers.

    Our research shows that Texas could free up 7 gigawatts or more of electric generating capacity through demand response, which would double what it has available today.

    Increasing demand response can be cheaper than building new power plants. While a new wind or solar farm might cost $1,000 or more per kilowatt of generating capacity, demand response programs cost about $200 per kilowatt of demand that can be turned off.

    It’s also faster. Technicians can install thousands of remote-controllable thermostats or appliance switches in months, compared with the years of lead time required to site, license and build new power plants.

    – Connect Texas’ isolated power grid to the Western and Eastern interconnections.

    Most electricity in the U.S. is generated and sold over two large grids that cover nearly all of the lower 48 states. Texas has kept its own grid inside state lines as a way to minimize federal regulation of its power sector. While there are some very weak direct-current ties to those grids, Texas utilities can’t import meaningful amounts of power when supplies are scarce, or export it when they have a surplus and neighboring states need support.

    US map showing Western and Eastern Interconnect and ERCOT grids.
    Most of Texas gets power from the state grid, managed by the Electric Reliability Council of Texas (ERCOT), which has limited interconnections with grids that deliver power over the rest of the continental U.S. ERCOT, CC BY-ND

    Expanded grid connectivity would make electricity supply in Texas more reliable and enable generators to export low-carbon power from the state’s abundant wind and solar farms. Rapid growth in wind and solar generation in Texas has saved the state’s consumers billions of dollars while making a lot of money for rural landowners and local governments.

    Those economically beneficial renewable power plants will eventually saturate the limited Texas market. Opening access to consumers in other states by connecting Texas to other grids would continue to spur economic growth and job creation in rural areas and would give the state grid a lifeline during extreme events. Our ongoing research shows that this would be a cheaper and cleaner way to assure reliability than just adding more natural gas power plants.

    Texas officials often tout the state’s “all of the above” energy strategy, but that vision focuses heavily on production. In our view, an approach that employs every tool in the toolbox—including efficiency, demand response and increased grid connectivity—would better serve the state.

    Michael E. Webber, Josey Centennial Professor of Energy Resources, The University of Texas at Austin; Drew Kassel, PhD Student in Mechanical Engineering, The University of Texas at Austin; Joshua D. Rhodes, Research Scientist, The University of Texas at Austin, and Matthew Skiles, PhD Student in Mechanical Engineering, The University of Texas at Austin

    This article is republished from The Conversation under a Creative Commons license. Read the original article.

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    Dr. Michael E. Webber is the Josey Centennial Professor in Energy Resources at the University of Texas at Austin and CTO of Energy Impact Partners, a $3 billion cleantech venture fund. From September 2018 to August 2021, Webber was based in Paris, France where he served as the Chief Science and Technology Officer at ENGIE, a global energy & infrastructure services company. Webber’s expertise spans research and education at the convergence of engineering, policy, and commercialization on topics related to innovation, energy, and the environment. His book Power Trip: the Story of Energy was published in 2019 by Basic Books with an award-winning 6-part companion series that aired on PBS, Amazon Prime and iTunes starting Earth Day 2020. His prior book, Thirst for Power: Energy, Water and Human Survival, which addresses the connection between earth’s most valuable resources and offers a hopeful approach toward a sustainable future, was published in 2016 by Yale Press and was converted into an hourlong documentary. He was selected as a Fellow of ASME (the American Society of Mechanical Engineers) and as a member of the 4th class of the Presidential Leadership Scholars, which is a leadership training program organized by Presidents George W. Bush and William J. Clinton. Webber has authored more than 400 publications, holds 6 patents, and serves on the advisory board for Scientific American. Webber holds a B.S. and B.A. from UT Austin, and M.S. and Ph.D. in mechanical engineering from Stanford University. He was honored as an American Fellow of the German Marshall Fund and an AT&T Industrial Ecology Fellow on four separate occasions by the University of Texas for exceptional teaching. Drew comes from the north, i.e., Wisconsin. He grew up in Milwaukee and graduated high school in 2017. He moved out to Madison for undergraduate studies and then graduated from the University of Wisconsin-Madison in 2021 with a Bachelor’s of Science in mechanical engineering. During his undergrad years, he began his research career as an undergrad assistant in a lab that studied fluid dynamics and the heat transfer properties of two-phase flow. Once graduated, he moved to Austin in the summer of 2021 to begin working toward a Ph.D. at The University of Texas at Austin within the Webber Energy Group. Drew’s research interests are in big picture energy systems and cleaning up the power grid. Currently, he is researching grid resilience scenarios in extreme weather events by studying what efforts are needed to prepare for increasingly probable extreme weather. The methods involved in this research are robust capacity expansion models of the ERCOT power grid infrastructure that can be modified to explore specific resilience plans. These plans typically involve grid interconnections, distributed energy resources, and storage options at utility and distributed scales. Ultimately, Drew will study the interactions between these three options on a case by case basis to determine what combinations of them might work in practice. Joshua D. Rhodes, Ph.D. is a Research Scientist at The University of Texas at Austin, a non-Resident Fellow at Columbia University, and a Founding partner and the CTO of IdeaSmiths LLC. His current work is in the area of smart grid and the bulk electricity system, including spatial system-level applications and impacts of energy efficiency, resource planning, distributed generation, and storage. He is also interested in policy and the impacts that good policy can have on the efficiency of the micro and macro economy. He is also a regular contributor to Forbes and is an AXIOS Expert Voice. He also sits on the boards of Catalyst Cooperative. He holds a double bachelors in Mathematics and Economics from Stephen F. Austin State University, a masters in Computational Mathematics from Texas A&M University, a masters in Architectural Engineering from The University of Texas at Austin and a Ph.D. in Civil Engineering from The University of Texas at Austin. He enjoys mountain biking, backpacking, and a good cup of coffee. As an NSF Graduate Research Fellow, Matt has conducted systems analysis research as it relates to power grid operations and sustainability. Currently, he is focused on assessing the role of energy efficiency and demand response in increasing power grid resiliency during extreme weather events. As part of this research, Matt characterizes electricity demand profiles using the ResStock building energy model developed by NREL. He uses the ResStock model to generate building stock that is statistically representative of current residential housing and apply efficiency retrofits and equipment upgrades to investigate different development scenarios. He has also focused on investigating the impact that weather conditions have on electricity demand for historical severe weather events and future climate change scenarios. Before joining The University of Texas at Austin, Matt earned a B.S. in civil engineering from the University of Wisconsin where he worked for several organizations conducting research to inform environmental and energy policy-making processes. After graduating, he worked as an engineer in the energy services industry implementing energy optimization projects at commercial and industrial facilities.

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