Colorado’s cleanest energy options are also its cheapest
New modeling shows the state can decarbonize — at a savings.
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Of all the states in the US, Colorado may be the best prepared for a genuine, large-scale energy transition.
For one thing, thanks to its bountiful sunlight and wind, Colorado has enormous potential for renewable energy, most of which is untapped. The state currently generates only 3 percent of its electricity from solar and just under 18 percent from wind.
The political climate is favorable as well. As of earlier
this year, Democrats have a “trifecta” in the state, with control over
the governorship and both houses of the legislature. Gov. Jared Polis
campaigned on a promise to target 100 percent clean electricity by 2040. In their last session, he and the legislature passed a broad suite of bills meant to boost renewable energy, reform utilities, expand EV markets, and decarbonize the state economy.
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Colorado has the three main ingredients it needs to get
going on clean energy: a healthy economy, plentiful sunlight and wind,
and Democrats firmly in charge of state government.
Over the last year or so, energy systems modeler and analyst Christopher Clack, with his team at the energy research outfit Vibrant Clean Energy
(VCE), has been taking a close look at what Colorado is capable of in
terms of clean energy, and what it might cost. (The research was
commissioned by renewable energy developer Community Energy.)
VCE has built a model called WIS:dom
(ahem, “Weather-Informed energy Systems: for design, operations, and
markets”). It can simulate the Colorado electricity system with
incredibly granular accuracy, down to a 3-kilometer, 5-minute range,
year-round. Using that tool, they have simulated various clean-energy
initiatives the state might take, and their impact.
I’ve been tracking their progress. In January, I wrote
about their initial finding, that Colorado could save $2.5 billion
through 2040 by shutting down all its coal plants. In August, I wrote about the second paper, which found that electrifying the state’s transportation fleet is the single biggest decarbonization step it could take and would save consumers money.
(This kind of modeling tells us nothing about the
political challenges of achieving these goals, of course. But it can
tell us what is possible.)
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Now the third report
is out, and it takes on the big question: Can Colorado decarbonize its
entire state economy in line with its ambitious goals? (The state’s newly passed climate law
sets targets of 50 percent decarbonization by 2030 and 90 percent by
2050.) Can it achieve deep decarbonization and still provide reliable,
affordable power?
Spoiler: Yes, it can.
The world may be a raging dumpster fire, but Colorado has
the potential to be an island of sanity, moving toward a cleaner,
cheaper, healthier energy system in a way that benefits all state
residents. Let’s take a look at the paper.
Three scenarios for Colorado, and the cleanest is the cheapest
VCE modeled three scenarios through 2040, using
conservative technology cost assumptions and minimizing the import of
energy from other states and the need for new transmission
infrastructure:
- Business as usual (BAU) keeps all active coal plants running;
- Retire coal pushes all active coal plants into retirement but otherwise lets the electricity sector evolve according to current economics (a mix of wind, solar, and natural gas); and
- Deep decarbonization retires all coal, drives down emissions in the power sector by expanding wind and solar and minimizing natural gas, and electrifies transport (80 percent EVs), space and water heating (60 percent heat pumps), and other sectors. (It also builds 200 MW worth of hydrogen-producing facilities in the state, to help get at the more difficult-to-decarbonize sectors.)
The first and perhaps most important thing to note is
that in all scenarios, Coloradans receive a stable, reliable supply of
electricity. There is no technical barrier to a mostly decarbonized
power sector; the state’s grid is perfectly capable of handling it.
The second thing to note is that in all scenarios,
average retail electricity rates decline over time, but they decline
most and fastest through deep decarbonization. Cleaner energy benefits
all Colorado ratepayers, not just those who have an EV or solar panels.
The most expensive option for Colorado consumers is to keep the coal plants running:
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Relative to BAU, deep decarbonization saves Coloradans
$4.8 billion in electricity costs through 2040. Of that, $1.5 billion is
invested in renewable energy, electrification, and storage
technologies, so the savings net out to $3.3 billion.
Third, deep decarbonization brings savings in other sectors as well. VCE reports:
The total savings between 2018 and 2040 for transportation are estimated to be $15.6 billion (real 2017$), which equates to a saving of almost $680 million per year. The total savings between 2018 and 2040 for heating are estimated to be $9.7 billion, which amounts to an annualized saving of $424 million. Therefore, the combined savings are $25.3 billion by 2040, at an annual average amount of approximately $1 billion.
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All told, that averages out to annual savings of $97 per
electricity customer, $528 per heating customer, and $611 per vehicle
through 2040. Not a bad deal for Coloradans.
When all the costs are tallied up — electricity,
transportation, and heating system costs — the deep decarbonization
scenario comes in the cheapest.
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And the cheapest method is also the cleanest
As the name indicates, the deep decarbonization scenario
reduces the most greenhouse gas emissions — about twice again what is
reduced by the retire-coal scenario.
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The key is that retiring coal only reduces emissions in
the electricity sector. Electrifying transportation and heating also
radically reduce emissions in those sectors.
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Overall reductions in greenhouse gas emissions in the
deep decarbonization scenario, VCE writes, “are more than 36% by 2025,
56% by 2030 and 69% by 2040 compared with 2005 levels.” Cumulatively
through 2040, 1 billion metric tons of carbon dioxide emissions would be
avoided. That would put Colorado in line with its legislative goals.
Deep decarbonization cranks up electricity demand and blows out solar and wind
By transitioning transportation, heating, and other
sectors over to the power grid, the deep decarbonization scenario
increases electricity demand relative to the other scenarios by about 25
percent.
The increase in electricity demand gives grid operators
more options. Energy storage, in the form of batteries and EVs, allows
much of this demand to be “shifted” to times of day when renewables are
more plentiful. A grid with more controllable electricity demand can integrate more renewable energy.
Here’s the kind of power that would be dispatched in the three scenarios:
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As you can see, in the retire-coal scenario, the lost
coal is replaced with a mix of solar, wind, and natural gas. In the deep
decarbonization scenario, coal and natural gas are both replaced
(though some residual natural gas remains), occasioning a huge rise in
solar, wind, and storage.
Interestingly, though deep decarbonization would mean more electricity demand, it would mean 10 percent lower overall energy demand, mainly because demand would decline in transportation.
Electric vehicles are inherently superior to internal combustion engines
in several ways. More of the energy they generate goes to motion, and
less to waste heat. “EVs convert about 59%–62% of the electrical energy
from the grid to power at the wheels,” says the Department of Energy.
“Conventional gasoline vehicles only convert about 17%–21% of the
energy stored in gasoline to power at the wheels.” With less energy
required to move the same distance, demand declines even if vehicle
miles traveled (VMT) don’t.
EVs also deliver more torque, for better acceleration.
There are fewer moving parts, so they break down less often and are
easier to service. All told, they are cheaper to own and require less
energy.
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Deep decarbonization means jobs
The “business as usual” model would create almost no
additional jobs in the electricity sector. Retire-coal would create some
in the early years, as coal plants are shuttered and capacity is built
to replace them, but then it would level off.
Deep decarbonization, on the other hand, would create
more jobs with each passing year, as enormous amounts of fossil fuel
capacity are replaced with enormous amounts of clean energy.
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This only stands to reason: if Colorado takes on the much
more ambitious task of deep decarbonization, it will take more work to
get there.
Cheap renewable energy is changing the whole picture
Obviously, in the real world, Colorado can’t just turn a
dial and switch its vehicle fleet to EVs, its residential furnaces to
heat pumps, and its natural gas power plants to solar and wind. All of
those things will require additional legislation and years of work.
There will be political costs, opportunity costs, and transition costs
along the way; it won’t be as smooth or efficient in practice as it
looks in these graphs.
But if the core story — that Colorado’s cleanest choice
is also its cheapest — seems too good to be true, it’s only because most
people have failed to fully grasp how cheap clean energy has gotten,
and how fast it’s getting cheaper.
Already in Colorado, wind+storage projects are bidding in at prices lower than the operational
costs of existing coal plants in the state; solar+storage projects are
cheaper than 75 percent of them. It costs less to shut the coal plants
down and replace them than to keep them running.
And given the falling costs of energy storage, it’s increasingly possible to envision phasing out natural gas as well, which is why the biggest power utility operating in Colorado, Xcel Energy, recently committed to going 100 percent carbon-free by 2050.
Low-cost renewable energy has endless knock-on effects.
Among other things, it means that it’s much, much cheaper to fuel a
vehicle with electricity than it is to fuel it with gasoline or diesel.
And it’s much cheaper over the long run to heat a building with an
electric heat pump than it is to burn natural gas. A large-scale
transition to electricity in those and other sectors will save consumers
enormous amounts of money.
What Clack’s modeling shows is that it is possible to
engineer such a transition while still providing reliable, low-cost
electricity to everyone in the state. There is no technical barrier, no
need for an entirely new grid, no need to wait on new technologies. The
main barriers now, in Colorado as in so many other places across the
globe, are social and political. The tools are at hand. All that’s
needed are will and courage.
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