The old, dirty, creaky U.S. electric grid would cost $5 trillion to replace. Where should infrastructure spending go?

In recent years, where we get our power has changed dramatically. The oldest generators are large power plants, with many located in the eastern part of the U.S. Most recent additions have been smaller and more spread out – think rooftop solar panels or wind farms. Some experts have even said that this model of more distributed generation closer to where power is consumed – along the edge of the network, rather than central power plants – is the new norm.

Going forward, we can either build the grid back the same way we’ve done before or we can invest in new technologies that can bring the same service but at a lower cost.

And how could we make it cleaner? Some people think the grid can run completely on renewable energy sources. Others say the best way to “decarbonize,” or reduce carbon emissions, for the energy system as a whole is widespread electrification of the industrial and transportation sectors.

But to answer what such transitions would cost, we need to know: What does the current grid cost? How much is all the concrete, steel, silicon, etc. that we have already installed in the ground currently worth? To help inform policymakers and planners grappling with their vision of the future, I set about to answer that question.

What makes up the grid?
For this exercise, I’ve limited “the grid” to the following parts:

1. Power plants

2. High and low-voltage transmission lines, which transport power over long distances

3. Distribution lines, which bring power directly to buildings or other end points

4. Substations for routing power on the transmission grid

5. Substations on the distribution grid

6. Transformers that change voltages on the distribution grid

This calculation leaves out additional and necessary components of the grid, such as the electric wire inside your home, meters at the electrical panels on homes and buildings and end-use devices that consume the electricity.

Combing through a variety of public reports and using updated estimates for new construction and standard approaches for estimating depreciation, we quantified the value of the nation’s assets for power generation, transmission and distribution.

The total capacity of these power plants is about 1.15 terawatts. That’s the generating capacity of about 1,000 nuclear power reactors (the United States currently has about 100). As you can imagine, that would be costly to replace. For power plants alone, the replacement value is nearly $2.7 trillion, and the depreciated value, or the rough current value, is nearly $1 trillion. Overall, the breakdown of the value is about 56 percent power plant, 9 percent transmission system and 35 percent distribution system.

What path forward?
If we want to have a cleaner energy future, there are multiple pathways to get there. However, I hypothesize that the cheapest and likeliest pathway will be the one that best leverages, not duplicates, the infrastructure we already have. One of the most “plug and play” pathways (and what we are seeing today) is a conversion from coal to gas-fired generation at power plants that can use existing wires, poles and water infrastructure.

At the other end of the spectrum, a hydrogen economy would require massive new investments in new kinds of technology, so it would leverage less of what we currently have. For instance, we’d need to build places to generate and store hydrogen. On the other hand, it has the potential to be more resilient and sustainable.

One area that does look promising for infrastructure investment is upgrading the bulk power transmission network. These upgrades could allow power to flow between regions of the United States and would be similar to how the interstate highway system drove down business costs across the country by greatly reducing the time it took to transport goods and services across our vast country.

There are areas of the United States where power is produced cheaper and with fewer environmental impacts than in other areas. Expanding transmission lines to areas of the country that have good wind and solar resources can bring very low-cost power to users. The problem is that these areas are not always where the people are, so to bring this power to the people, we need a strong transmission network.

Distribution networks – the part of the grid that delivers power directly to buildings – can also integrate more solar without much added cost to the grid’s operation. But once solar capacity reaches a certain percentage of power demand on the local network, which varies by location, then more costs are incurred.

In the end, consumers, or taxpayers, always end up paying for these upgrade projects, but the benefits can outweigh costs. Texas’s expansion of its electric grid has allowed for much more wind power to reach load centers which, along with a drop in natural gas prices, has driven down the wholesale electricity market costs. Those lower costs are then passed along to ratepayers.

There is no path that does not require investment – even just maintaining what we have will cost hundreds of billions, if not trillions, of dollars over the next decade. The bigger question is: As we continue to replace and rebuild this amazing grid, what technologies should we focus on?

Joshua D. Rhodes is Postdoctoral Researcher of Energy, University of Texas at Austin. This article is published courtesy of The Conversation (under Creative Commons-Attribution / No derivative).