Solar and wind keep getting cheaper as the field becomes smarter

Solar and wind keep getting cheaper as the field becomes smarter

Dyllan Furness

As solar and wind energy ramps up in the United States, the industries have gotten better at installing and operating their facilities. This experience can be seen in how the facilities are financed. According to new research, people working in the fields—and adjacent ones—have learned to be more efficient, reducing the overall cost of power. Further, according to Mark Bolinger, a research scientist at Lawrence Berkeley National Laboratory and one of the authors of the paper, this so-called learning rate can be extrapolated into the future, and it spells good news for the two renewable sources of energy.

“The people who operate these turbines naturally get better over time as they do more of it. They get more efficient, and it allows them to lower their costs a bit,” Bolinger told Ars, adding that the same holds true for the workers manufacturing the facilities. “Some of them have been doing it for a really long time… All things being equal, that should lead to a reduction in manufacturing costs.”

There’s a large amount of literature on learning rate and learning curve theory, he said. Moore’s Law, which pertains to the power of silicon computer chips, says that the number of transistors per silicon chip doubles each year. Bolinger said that the learning rate in these renewable energy operations is similar to that. Learning rate is a measure of how much cost declines for each doubling of cumulative output, he said.

This research into learning rates in the solar and wind industries began in early 2021. The researchers started to pull together the plant-level data they needed to calculate the levelized costs of energy (LCOE) for all of the wind and solar plants they studied. According to Bolinger, LCOE is made up of several components. The most important is the upfront installed cost, or capital cost, of the plant. This is followed by the capacity factor, the measure of how much energy the plant can produce each year—this is, in turn, a function of where the plants are located and how much wind or sun they receive. LCOE also factors in operating costs, government tax rates, financing costs, and expected useful lifetimes of the plants. “[LCOE] is essentially spreading costs across the full lifetime of those plants,” he said.

Git gud

In all, the team looked at data from 908 wind farms and 822 solar operations in the United States. The plants are all larger than five megawatts in capacity. For the wind farms, the team collected data from now until 1982, which is basically when the modern, utility-scale wind farm hit the US. For solar, the data goes back to 2007, which is when the first utility-scale solar photovoltaic projects larger than five megawatts were built in the US. The team studied this data until 2020 for both renewables.

The research found that the people operating the solar and wind farms are learning to do so more efficiently, lowering the LCOE. The same is true for financing the plants, he added. When an industry is young, it’s considered to be risky, so the cost of financing is high. But as experience in the industry grows, lenders and investors become more comfortable with the assets and are willing to offer more competitive rates, which also leads to lower costs. “It’s not just the upfront capital costs that can benefit from learning. Instead, it’s [that] really all five or six LCOE inputs can benefit from learning by doing over time. All of them can contribute to lower costs.”

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