This article is the first in a series titled “Real Talk on Reliability,” which will examine the reliability needs of our grid as we move toward 100% clean electricity and electrify more end-uses on the path to a climate stable future. It was written by Michelle Solomon, a senior policy analyst in the Electricity Program at Energy Innovation.
The beginning of summer brings with it sunshine and vacations for many, but increasingly these warm months are accompanied by extreme heat, a symptom exacerbated by climate change. As a result of widespread heat-waves, people and businesses crank their air conditioners for relief, increasing electricity demand and adding stress to the grid. At the same time, electricity is getting cleaner — in 2022, the United States generated 40% of its electricity from carbon-free sources, including 15% overall from wind and solar energy, both of which are now the cheapest sources of electricity, and the fastest growing.
To help prepare the nation’s electricity grid for the season ahead, the North American Electric Reliability Corp. recently released its annual summer reliability assessment. The report examined the United States and Canada’s ability to meet expected summer electricity demand, including an evaluation of the risks associated with wildfires and drought, and provided short-term recommendations on how to overcome potential shortfalls.
NERC’s findings follow a trend of the last several years, highlighting that while electricity supply is sufficient across the country under normal summer conditions, during extreme heat, several regions are at risk for supply shortfalls. NERC cited the retirement of aging and expensive fossil fuel power plants as a factor in this dynamic, but also found that “increased and rapid deployment of wind, solar, and batteries make a positive difference this year,” highlighting that one of the most important tools bolstering reliability is adding new, clean generation capacity.
As we move toward a cleaner electricity system, reliability is of increasing focus for policymakers, utilities, system operators and electricity consumers alike, and for good reason — lives depend on the power staying on.
Our grid is undeniably in transition. The shift to clean electricity and electric end-uses is picking up pace in response to federal policy and incentives, state clean energy goals and utility leadership. In 2022, wind and solar accounted for 74% of new utility-scale generating capacity, while new natural gas capacity made up only 25%. Battery storage has also seen a meteoric rise with the addition of 4 GW across the country last year in a near doubling of storage capacity. This fast-growing addition of renewables and storage is welcome as electricity demand increases and uneconomic fossil fuel plants retire. Other demand-side resources and operational changes are also in the toolbox as grid operators work quickly to manage the transition without impacting grid reliability, safety and affordability.
With all of these changes to the physical system, we need to evolve the way we think about reliability. Ric O’Connell, executive director of GridLab, highlights that one of the biggest misconceptions in the energy transition is the need for baseload power, or plants that are expensive to build but cheap to operate and therefore run almost all the time. O’Connell explains that “we know we need a portfolio of resources on the grid that, working together, can provide resource adequacy, or energy when we need it, but that portfolio does not necessarily need to include baseload or 24/7 resources.”
While the shift to this new paradigm presents challenges, we are gaining confidence in the reliability of a clean grid. Previously there was “trepidation about even adding small amounts of weather-dependent power sources like wind and solar to the grid,” said O’Connell. “Now, large, sophisticated grids in the Midwest, Texas, and California regularly run on a 70% or higher share of wind and solar for hours at a time.” We have proven examples of smaller grids running at even higher percentages of weather dependent resources — the island of Kauai has been able to run on 100% renewable energy for at least nine hours at a time. Multiple studies show that the U.S. grid can run on up to 80% clean electricity with the technology that is available today.
To build this portfolio, utilities, regulators and grid operators will need to be able to accurately evaluate each resource’s contribution to resource adequacy and operational reliability. As Federal Energy Regulatory Commissioner Allison Clements recently said, “Reliability discussions will lead to the more cost-effective solutions if they start with the data-driven analytical work required to understand and quantify the problem that we are aiming to solve.”
The nuts and bolts of reliability
While the grid shifts from a still fossil fuel-heavy system to one that is powered by clean, carbon-free electricity generation, there are three questions we need to answer. First: can a clean, carbon-free grid offer the same or better reliability than we have today? Second: can the grid be reliable as we are transitioning? And third: can a clean grid meet the demand from more electrified end-uses without compromising reliability? This series will aim to demonstrate that the answer to these questions is “yes”, but not without the correct planning and policies in place.
Before answering the above questions, it’s helpful to understand the basics of electricity reliability — a term used often, but not always consistently. There are four separate but interconnected pieces to ensuring that power from the grid is reliable.
- First is resource adequacy, which means having enough energy to meet demand — either in the form of supply-side generation or demand-side distributed resources.
- Second is reliable operation of the grid, including generation, transmission and distribution of electricity — the monitoring and control of the system, balancing energy supply to match the demand and ensuring transmission lines and facilities stay within their safe operating limits.
- Third is resilience, which is the ability of the electricity system and other connected systems — like transportation, health, and safety — to ride-through or bounce back quickly in the face of outages.
- Connected to resilience is grid hardening, which refers to a myriad of technology and operational solutions that help the grid withstand these major events without disruption.
Reliability is a characteristic of the whole electricity system, to which individual resources contribute, and with respect to resource adequacy, no resource is available 100% of the time. For instance, while wind and solar vary over the course of the day, year, and with the weather, fossil fuel plants increasingly experience forced outages during extreme weather as seen by recent Winter Storms Uri and Elliott. Maintaining a reliable grid requires valuing every resource’s impact accurately, and building a generation portfolio that balances supply and demand throughout the day and year.
When electricity supply and demand are matched, the electricity flows through the grid at a constant frequency and voltage but as supply and demand vary throughout the day, frequency and voltage can begin to fluctuate. Grid services are the contributions that different resources provide to maintain stability such as frequency response, voltage regulation and more. Historically, spinning turbines powered by gas, coal and nuclear helped ensure stability, though new solutions can compete to fill this role as public acceptance, policy, finance and economics push conventional resources to retire. The ability of wind, solar and batteries to provide grid services compared to spinning turbines is detailed in the below figure from Milligan Grid Solutions.
In order to maintain reliability and ensure the transition goes as smoothly as possible, policymakers will need to remove barriers to building new, clean resources and connecting them to the grid. With nearly double the current U.S. generating capacity just waiting in interconnection queues across the country, new transmission lines are the “biggest barrier to adding sufficient new clean energy,” according to O’Connell, and “policy plays a critical role in how we plan, permit, and pay for transmission. Good policy means we can get the transmission built in the timeframe we need, so clean energy can come online and maintain reliability.”
Additional federal leadership is essential, but while the recent debt negotiations considered several transmission reform policies, the ultimate outcome lacked substantive action. Distribution system upgrades are needed to support more electrified end-uses, such as heat pumps and electric vehicles, which can also be hindered by regulatory and utility processes if they aren’t anticipated.
A clean, reliable grid capable of supporting mutual goals of decarbonization and electrification is possible, but it won’t happen on its own. The rest of this series will cover deep dives on key topics in grid reliability including: the future of reliability services with clean energy, supply- and demand-side approaches to keeping the grid reliable, the impacts of extreme weather and climate change, and the need for clean, firm power.