Underground water could be the solution to green heating and cooling
Decarbonizing the grid means storing energy from renewables. Aquifers can
do that.

Date:
April 5, 2023
Source:
DOE/Lawrence Berkeley National Laboratory
Summary:
About 12% of the total global energy demand comes from heating
and cooling homes and businesses. A new study suggests that using
underground water to maintain comfortable temperatures could reduce
consumption of natural gas and electricity in this sector by 40%
in the United States.

The approach, called aquifer thermal energy storage (ATES), could
also help prevent blackouts caused by high power demand during
extreme weather events.


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FULL STORY ========================================================================== About 12% of the total global energy demand comes from heating and cooling homes and businesses. A new study suggests that using underground water
to maintain comfortable temperatures could reduce consumption of natural
gas and electricity in this sector by 40% in the U.S. The approach,
called aquifer thermal energy storage (ATES), could also help prevent
blackouts caused by high power demand during extreme weather events.


==========================================================================
"We need storage to absorb the fluctuating energy from solar and wind,
and most people are interested in batteries and other kinds of electrical storage. But we were wondering whether there's any opportunity to
use geothermal energy storage, because heating and cooling is such a predominant part of the energy demand for buildings," said first author
A.T.D Perera, a former postdoctoral researcher at Lawrence Berkeley
National Laboratory (Berkeley Lab), now at Princeton University's
Andlinger Center for Energy and Environment.

"We found that, with ATES, a huge amount of energy can be stored, and
it can be stored for a long period of time," Perera said. "As a result,
the heating and cooling energy demand during extreme hot or cold periods
can be met without adding an additional burden on the grid, making urban
energy infrastructure more resilient." The study, published this week
in Applied Energy, is one of the first examinations of how ATES could
fit into the larger goal of decarbonizing U.S.

energy systems by storing intermittent renewable energy to use when the
sun isn't shining and the turbines aren't spinning. After building a comprehensive technological and economic simulation of an energy system,
the authors found that ATES is a compelling option for heating and cooling energy storage that, alongside other technologies such as batteries,
could help end our reliance on fossil fuel-derived backup power and
enable a fully renewable grid.

Putting thermodynamics to work ATES is a delightfully simple concept that leverages the heat-absorbing property of water and the natural geological features of the planet. You simply pump water up from existing underground reservoirs and heat it at the surface in the summer with environmental
heat or excess energy from solar, or any time of the year with wind. Then
you pump it back down.

"It actually stays fairly hot because the Earth is a pretty good
insulator," explained co-author Peter Nico, deputy director of the Energy Geosciences Division at Berkeley Lab and lead of the Resilient Energy,
Water and Infrastructure Domain. "So then when you pull it up in the
winter, months later, that water's way hotter than the ambient air and
you can use it to heat your buildings. Or vice versa, you can pull up
water and let it cool and then you can put it back down and store it
until you need cooling during hot summer months. It's a way of storing
energy as temperature underground." ATES is not yet widely used in the
U.S., though it is gaining recognition internationally, most notably in
the Netherlands. One major perk is that these systems get "free" thermal
energy from seasonal temperature changes, which can be bolstered by the addition of artificial heating and cooling generated by electricity. As
such, they perform very well in areas with large seasonal fluctuations,
but have the potential to work anywhere, so long as there is wind or
solar to hook up to. In regards to other impacts, ATES systems are
designed to avoid impinging upon critical drinking water resources --
often the water used is from deeper aquifers than the drinking water
supply -- and do not introduce any chemicals into the water.

How does it perform? To get some concrete numbers estimating how much
energy ATES could save on the U.S. grid, and how much it would cost to
deploy, the team designed a case study using a computational model of a neighborhood in Chicago. This virtual neighborhood was composed of 58 two-story, single-family residence buildings with typical residential
heating and cooling that were hooked up to a simulation of an energy
grid with multiple possible energy sources and storage options, including
ATES. Future climate projections were used to understand how much of the neighborhood's total energy budget is taken up by heating and cooling
demands currently, and how this might change in the future. Finally,
a microgrid simulation was designed for the neighborhood that included renewable energy technologies and ATES to evaluate the technoeconomic feasibility and climate resilience. Putting all these factors together
into one model would not have been possible without the team's diverse expertise across the energy geosciences, climate science, and building
science fields.

The results showed that adding ATES to the grid could reduce consumption
of petroleum products by up to 40%, though it would cost 15 to 20%
more than existing energy storage technologies.

"But, on the other hand, energy storage technologies are having sharp
cost reductions, and after just a few years of developing ATES, we could
easily break even. That's why it's quite important that we start to
invest in this research and start building real-world prototype systems,"
said Perera.

"ATES does not need space compared with above-ground tank-based water
or ice storage systems. ATES is also more efficient and can scale up for
large community cooling or heating compared with traditional geothermal
heat pump systems that rely on heat transfer with the underground earth
soil," added Tianzhen Hong, a co-author and senior scientist at the
Building Technology and Urban Systems Division.

Another major benefit of ATES is that it will become more efficient
as weather becomes more extreme in the coming years due to climate
change. The hotter summers and harsher winters predicted by the world's
leading climate models will have many downsides, but one upside is that
they could supercharge the amount of free thermal energy that can be
stored with ATES. "It's making lemonade, right? If you're going to have
these extreme heat events, you might as well store some of that heat
for when you have the extreme cold event," said Nico.

ATES will also make the future grid more resilient to outages caused by
high power demands during heat waves -- which happen quite often these
days in many high-population U.S. areas, including Chicago -- because ATES-driven cooling uses far less electricity than air conditioners,
it only needs enough power to pump the water around.

"It's very much a realistic thing to do and this work was really about
showing its value and how the costs can be offset," said Nico. "This
technology is ready to go, so to speak. We just need to do it."
This research was funded by the Department of Energy's Geothermal
Technologies Office.

* RELATED_TOPICS
o Earth_&_Climate
# Energy_and_the_Environment # Renewable_Energy #
Sustainability # Environmental_Science # Water # Weather #
Environmental_Issues # Tundra
* RELATED_TERMS
o Renewable_energy o Solar_power o Hydroelectricity o Wind_power
o Climate o Desalination o Water_scarcity o Radiant_energy

========================================================================== Story Source: Materials provided by
DOE/Lawrence_Berkeley_National_Laboratory. Original written by Aliyah
Kovner. Note: Content may be edited for style and length.


========================================================================== Journal Reference:
1. A.T.D. Perera, Kenichi Soga, Yujie Xu, Peter S. Nico, Tianzhen Hong.

Enhancing flexibility for climate change using seasonal energy
storage (aquifer thermal energy storage) in distributed
energy systems. Applied Energy, 2023; 340: 120957 DOI:
10.1016/j.apenergy.2023.120957 ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2023/04/230405130132.htm

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