What combination of power generators on the U.S. grid produces reliable power at the lowest cost? Or, what’s the most renewable energy that can be deployed at a given grid power cost, and what kind of transmission capacity is needed to support it? How would the U.S. grid be different if it were one, unified grid with more high-voltage direct current (HVDC) transmission capacity? What’s the most productive design for a wind farm? How might weather and a changing climate affect future electricity production from wind and solar farms? And how much renewable power is really feasible on the U.S. grid?
These have been devilishly difficult questions to answer, but now advanced mathematical simulations are beginning to make it possible to answer them much more quickly…and if quantum computing becomes a reality, we could answer them instantly.
In an homage to Comedy Central’s Drunk History, this episode features a conversation conducted over several pints of IPA with a mathematician who recently developed such a simulator while he was working at NOAA (the National Oceanic and Atmospheric Administration) in Boulder, CO. His insights on how the grid of the future might actually function are fascinating, and will likely shatter some of your pre-existing beliefs. It also contains a few nuggets for the serious math geeks out there.
It is widely assumed that the ongoing migration of rural peoples to mega-cities all over the world will help reduce humanity’s per-capita energy footprint, while giving people a higher standard of living and accelerating energy transition. But the world is full of old, inefficient cities in desperate need of an eco-makeover, and of experts who understand the principles of “smart urbanization” and who can help identify how to transform a city from brown and dumb to smart and green. What’s the potential for replacing concrete with living things in cities? How can autonomous and electric vehicles help make cities cleaner and more livable? Why isn’t China promoting its phenomenal success with e-bikes to the rest of the world? Is China’s commodity demand going to continue to weaken as it moves away from a manufacturing economy? And will the emissions it was generating just move elsewhere when it does? All these questions and more are answered in this wide-ranging conversation with an expert on smart urbanization and China.
Although it’s clear enough that energy transition is necessary and reasonable, and although we know that transition is mainly happening on the grid at first, there is still much uncertainty about exactly where on the grid different strategies can be tried, how much they can accomplish, and what they’ll cost, relative to the alternatives….not to mention how the rest of the grid will respond as different measures—like storage, demand response, rooftop solar, controlled dispatch, and so on—are implemented. What’s needed to answer all these difficult questions? Better models, including serious math, by serious researchers.
Fortunately, one of those researchers is willing and able to explain several years of her work in grid modeling at NREL and elsewhere. So tune in and put on your thinking caps, because this episode (Geek Rating 10!) is not for the faint of heart.
As the world continues to struggle with the effects of climate change, energy transition is more important than ever as a key pathway to stopping global warming. But will it be enough? Many serious climate researchers think it won’t be, and urge deliberate attempts to directly alter the Earth’s climate by using a number of technologies, loosely grouped under the heading of geoengineering. But geoengineering has not won much support from the climate and environmental communities, and still struggles to gain enough legitimacy to attract sufficient research funding to attempt serious pilot projects that might tell us whether geoengineering holds real promise as a safe, cost-effective, and powerful tool in a portfolio of climate change mitigation strategies.
So what is the real potential of geoengineering to address climate change? How much would it cost? How risky is it, and what justification might there be for taking that risk? And what sorts of attitudinal shifts might be needed within the climate and environmental communities to embrace geoengineering as one of a portfolio of strategies? We attempt to answer all of those questions and more in this interview with a veteran science journalist and author of a recent book on geoengineering.
Energy and water are inextricably linked: It takes energy to supply water, and it takes water to supply energy. And those processes consume vast amounts of both. Yet we have only really begun to study the energy-water nexus and gather the data that policymakers will need to understand the risk that climate change poses to both power and water. As rainfall and temperatures continue to depart from historical norms, forcing conventional power plants to throttle back or shut down, we may need to invest more heavily in wind and solar PV just to keep the lights on. Even more radical solutions may become necessary, like switching to more dry-cooled power plants, and desalinating brackish groundwater. Ideally, we would treat the challenges of the energy-water nexus in an integrated way, deliberately reducing our energy and water demands simultaneously as part of our energy transition strategies, but our governments aren’t typically set up for that, and much more basic research and analytical work is needed.
What if we didn’t have to work around the grid we have today, with all of its inertia and incumbents and inflexibility? If we could start over and design the grid from scratch, what would it look like? And once we understood that, how might it change the way we are going about energy transition now, in order to reach that goal more quickly and directly? If what we really want is a grid that is fair, equitable, reliable, efficient, resilient, sustainable, and which serves our climate and social goals, what are the first principles we might work from, and what mechanisms might get us where we want to go? This freewheeling conversation aims to help all of us “think outside the box” a bit more, and imagine what the possibilities might be if we could just start over.
Should we tweak our markets to keep nuclear plants alive, or forget about markets and pay for them another way… and do we really need them at all to keep the grid functioning? Is nuclear power really declining because of overzealous environmentalists, or are there other reasons? Is it possible to balance a grid with a high amount of variable renewables and no traditional baseload plants? Is cost-benefit analysis the right way to approach energy transition? How much “decoupling” can we do between the economy and energy consumption, and how can we correctly measure it? Why are we so bad at forecasting energy and economic growth, and how can we do it better? How will energy transition affect the economy?
We explore all of these questions and more, and try to separate fact from falsehoods in this wide-ranging interview. It might even change your mind about a few things.
Is conventional, free-market economic theory really up to the task of energy transition and combating climate change? Can we let the so-called invisible hand of the market guide us through the troubled waters ahead, or will we need firm policy direction and deliberate, top-down planning to secure the best outcomes? How useful can free markets be, in transitioning us away from coal, and meeting our climate targets and securing enough carbon-free power to run our societies? Will they be any help at all in supporting technologies like carbon capture and sequestration, or geoengineering? Can negative discount rates help us pay for climate change mitigation projects? And what does the future hold for oil? We discuss all of these questions and more with veteran energy editor Ed Crooks of the Financial Times.
Multilateral Development Banks (MDBs) like the World Bank, the African Development Bank and the Asian Development Bank are publicly committed to ending energy poverty and enabling energy access to the developing world. But their conventional processes and approaches to risk management make it difficult for them to invest in the decentralized renewable energy solutions that have the best chance of lifting people out of energy poverty. So what can be done about it? To find out, we talk with a pioneer in the energy investment and energy access space and ask her some pointed questions about how development bank funding works, and how it needs to be changed.
Utilities face a host of rapid changes in a what used to be a staid business: new business models, changing supply and demand forecasts, new distributed architectures, new types of resources, new participants in the power grid that they don't control…yet they still must maintain a highly reliable power grid that operates within fairly narrow parameters.
Meanwhile, difficult questions remain to be solved, about how we’re going to manage our grid power transition, who the winners and losers will be, what destination we’re headed for, what role consumers and “prosumers” will play in the future, and what our reasons are for executing transition the way we do.
We tackle all of these issues in this wide-ranging, very geeky conversation about the “blocks and squiggles” of the grid of the future. Grid power transition, the rebound effect, energy efficiency, utility business models, cutting-edge grid power management considerations, regulation and rate design, electric vehicles as distributed energy resources… they’re all here.