A quarter of the world’s greenhouse gas emissions comes from heating and electricity. In this episode of Unfold, we talk with Alissa Kendall, professor in the Department of Civil and Environmental Engineering about our energy use. We’ll discuss renewable energy and other decarbonizing technologies and the importance of life-cycle analysis when discussing climate change solutions.
In this episode:
, professor, Department of Civil and Environmental Engineering
Episode Transcript
Amy Quinton: Hey, Kat. We haven't yet talked about one of the largest sources of greenhouse gas emissions.
Kat Kerlin: You must be talking about energy. Yep. And specifically, the energy it takes to produce heat and electricity worldwide.
Kat Kerlin: That's something like a quarter of all emissions.
Amy Quinton: But there's a silver lining when it comes to the energy sector, particularly here in the U.S. I learned that from Alissa Kendall. She's a professor of civil and environmental engineering here at ٺƵ.
Alissa Kendall: Our electricity sector is one of the sectors that we are actually decarbonizing, albeit not quickly enough. But we are able to replace fossil fuels with renewables. So we have replaced a lot of coal-fired power plants with natural gas-fired power plants. Natural gas still has a lot of greenhouse gas emissions, but per unit of energy generated, it's a lot less than coal.
Kat Kerlin: And speaking of coal, this year, for the first time on record, the U.S. is now producing more electricity from renewable power than from coal.
Amy Quinton: That's right. Electric utilities are retiring aging coal plants. And, well, the pandemic has pushed coal production into a deep crisis with reduced electricity use and the economic downturn.
Kat Kerlin: But that's good news for the climate, as coal is the dirtiest of all fossil fuels.
Amy Quinton: And even if coal makes a rebound, major utilities and technology companies are increasingly turning to renewables.
Kat Kerlin: In part, that's because renewables are cheaper than coal. Yeah, but there's a lot to unfold when looking at our energy future.
Amy Quinton: And Alissa is going to help explain it all in this brief bonus episode of Unfold.
Theme: Climate models all agree that temperatures are going to increase. It's going to be hotter. It's going to be drier. Fires going to burn more frequently. Maybe this is never going to be the way it was again. We need to come up with ways to literally pull CO2 out of the atmosphere. How are we going to work together to solve a challenge like climate change?
Amy Quinton: Coming to you from our closet studios as we shelter in place across the Sacramento region, this is Unfold, a ٺƵ podcast that breaks down complicated problems and discusses solutions.
Amy Quinton: This week, we unfold “decarbonizing energy.” I'm Amy Quinton.
Kat Kerlin: And I'm Kat Kerlin.
Amy Quinton: So, Kat, guess what, the biggest problem is when trying to decarbonize the energy sector and rely more on renewables?
Kat Kerlin: The fossil fuel industry lobby?
Amy Quinton: Likely, yes. But technically speaking, Alissa says there's a big drawback to most renewable power right now.
Alissa Kendall: The problem with electricity is that at a certain point, it becomes very hard to get rid of our natural gas-fired power plants or our coal-fired power plants if they're still around, because we need some source of very reliable electricity.
Kat Kerlin: Renewables like wind and solar aren't as reliable because, well, the sun doesn't shine all the time and the wind doesn't blow all the time. So we have this intermittent power conundrum. Right.
Amy Quinton: Important to point out here, though, that a UC Irvine study found that solar and wind could meet 80 percent of U.S. electricity demand. But like Alissa said, it's that last little bit that is a giant hurdle and requires substantial investment.
Kat Kerlin: But wait, Amy, aren't we finding ways to store energy from renewables so we don't have to worry about intermittent power... like big batteries?
Amy Quinton: Well, that's what I thought. But while we can store renewable energy with batteries, it's not for as long as we might need. Alissa says when we start looking at storing it reliably for the grid for extended periods of time - let's say a few weeks of sunless skies - batteries aren't a great option.
Alissa Kendall: If we think about investing large amounts of money and materials, which would have environmental impacts of their own, if we think about investing all of those to build enough storage capacity to meet these sort of extended gaps in renewables, the economics don't pan out and the environmental impacts don't always pan out either, meaning we might be increasing environmental impacts by investing in a huge amount of battery storage.
Kat Kerlin: So batteries have a big environmental impact.
Amy Quinton: Lithium ion batteries require lithium, obviously, but they also require heavy metals like cobalt and nickel and mining.
Kat Kerlin: Those materials can cause all sorts of pollution problems. We don't want to solve one problem by creating another.
Amy Quinton: It's interesting you said that because Alissa mainly analyzes the full lifecycle of products, technologies and even policies. And she says it's really critical that we do this.
Kat Kerlin: That makes sense, because if you think about this on a broader scale, we don't want to just reduce greenhouse gas emissions to fight global warming. We want to improve the environment for everyone.
Amy Quinton: Alissa became interested in life-cycle analysis when she was just a 22-year-old engineer working in the auto industry, and she worked on some of the very first electric vehicles on the market.
Alissa Kendall: I also lived right near a coal fired-power plant in Michigan, and the vehicles we were designing at the time were not very efficient. And I kept thinking, are we really helping the environment? At the time most of us were a lot more concerned with air quality from vehicles than we were with climate change. But still, the question was, are we really doing better? So I thought I invented this new way of looking at the issue. Right?
Amy Quinton: So like all good engineers, she went to work figuring it out.
Alissa Kendall: I sat down to try to pencil out like, well, what do the emissions really look like from this vehicle that we're designing? And in the conditions that we were operating in, the gasoline vehicle was much better.
Kat Kerlin: Wait. What? She compared a gasoline car to an electric car and found the gas car was better for the environment?
Amy Quinton: Yeah. Can you believe it? I mean, here is why. She was basing her research on the car operating in a cold climate. And cold climates make batteries less efficient. And electric vehicles also, of course, use electricity. And if your electricity comes from a coal-fired power plant and not renewables, then you get a dirty car.
Kat Kerlin: So that's not to say that electric cars are bad for the environment. You just need to look at more than tailpipe emissions to think about how the car was made, what resources went into building it and where your electricity sources are coming from. So, yeah, the entire lifecycle.
Amy Quinton: Right. It's fine to have an electric car in California. Because a lot of our electricity comes from renewables. But Alissa says it's really important we look at the lifecycle when examining climate change solutions, too.
Alissa Kendall: We want to make sure that when we're designing something new or trying to find a better solution, that we're not sort of causing impacts either in a different environmental category that is really important or up the supply chain somewhere else. So lifecycle assessment is really important for climate change choices because we don't want to invest in something that seems like it has lower emissions, but causes a whole lot of emissions somewhere else that we can't see.
Kat Kerlin: Speaking of better solutions, did Alissa talk about other renewable sources of energy that look as promising as wind and solar?
Amy Quinton: Well, we talked a little bit about tidal and wave energy, but there you have a ton of transmission issues. If you live near the coast, that might be OK, but other potential renewable sources that she talked about, one of them was green hydrogen, which is something I really hadn't heard much about before.
Kat Kerlin: Yeah. What's green hydrogen? Is that like hydrogen fuel cells?
Amy Quinton: No, it's essentially sort of making hydrogen from renewables. She gave me one example. In Northern Europe, Alissa says there's a tremendous amount of wind power there off the ocean, but there isn't the transmission capacity to move it where the demand is.
Alissa Kendall: So one of the innovations that's been pioneered, Germany has, I think, two sites that have done this, where they take that electricity, they split water and they generate hydrogen and they put the hydrogen into what has historically been natural gas lines. Usually they blend it with natural gas, but that decarbonizes the natural gas that they use a bit by blending in renewable hydrogen. It makes the natural gas a bit more energy dense, meaning per unit of gas there's more energy in there. And so they've been able to add some low carbon fuel essentially to the natural gas system because they have this excess wind capacity.
Amy Quinton: So plans are in the works here for a green hydrogen power plant. Los Angeles Power and Water wants to convert an old coal plant and Utah into a plant that runs on green hydrogen by 2045. It wouldn't be using excess wind power like they are in Europe, but they'd slowly convert natural gas to hydrogen.
Kat Kerlin: It sounds like it's going to take some innovative solutions to get us to 100 percent renewable power.
Amy Quinton: Yeah, and it's going to take more than that to combat climate change. I asked Alissa how hopeful she was that we can find solutions.
Alissa Kendall: In terms of optimism, I do think if you'd asked me 10 years ago, I would have just said we need to mitigate, meaning we need to reduce, reduce, reduce emissions. We still need to do that. But I actually think we need sort of a moonshot initiative in terms of solutions. And that means we have to worry about adaptation meaning, how we can help people who are going to be displaced or from where they live or where they grow their food. But we also need to come up with, like carbon negative technologies now. That means we need to come up with ways to literally pull CO2 out of the atmosphere. And if we don't do that, we're not going to get where we need to be.
Kat Kerlin: So we really need technologies to sequester carbon. Easy.
Amy Quinton: All right. Well, you know, Alissa is an engineer, so, of course, we can come up with carbon negative technologies. She actually was pretty hopeful about it all.
Kat Kerlin: You can find out more about Alissa Kendall and renewable energy at our website, ucdavis.edu/unfold. I'm Kat Kerlin.
Amy Quinton: And I'm Amy Quinton. Thanks for listening.
Credits: Unfold is a production of ٺƵ. It's produced by Cody Drabble. Original music for Unfold comes from ٺƵ alumnus Damian Verrett and Curtis Jerome Haynes.