If the future of energy is
the ability to cheaply and safely store intermittent renewables, then there’s
lots of good news on the battery front.
Renewable plus storage means
decarbonizing the grid. Public policy argues that’s something we should do
effectively and as quickly as possible.
One of the problems is that
batteries haven’t been up to the task. Some are too expensive, some are too
toxic, some are too fragile, some lose too much energy charging and
discharging, some die too soon and need to be replaced.
The list goes on.
But there’s amazing work being done globally on battery technology. We have reviewed some of that in an
earlier series that starts here.
But since that 2013 series,
there’s lots of new stuff. We’ll review a couple of innovations here, starting with flow batteries. .
Researchers at Harvard have
been looking for non-toxic alternatives to flow batteries using bromide
electrolytes. Flow batteries have energy-rich electrolytes in external tanks, and the electrolytes are pumped through the battery, meaning battery
capacity can be increased simply by increasing electrolyte storage.
“Harvard chemistry professor Roy
Gordon said they found a formulation using cheap, common materials that “deliver
the first high-performance, non-flammable, non-toxic, non-corrosive and
low-cost chemicals for flow batteries. They reported their research in the Sept. 25
issue of Science.
Project chief investigator
Michael Aziz said it would be a great way to store solar power: “"This is
chemistry I'd be happy to put in my basement. The non-toxicity and cheap,
abundant materials placed in water solution mean that it's safe -- it can't
catch on fire -- and that's huge when you're storing large amounts of
electrical energy anywhere near people."
Scientists at Ohio State have
combined a solar cell and a battery in what they’re calling an aqueous solar
flow battery. It’s still a ways from commercial production, but its inventors
believe it has a lot of potential.
"This solar flow battery
design can potentially be applied for grid-scale solar energy conversion and
storage, as well as producing 'electrolyte fuels' that might be used to power
future electric vehicles," said lead author Mingzhe Yu. They reported their findings in the Journal of the American Chemical Society.
Stanford researchers have
written about their new aluminum battery, which they say is fast-charging,
inexpensive and lasts a long time. They believe it can replace alkaline and
lithium-ion batteries. How fast a charge? Think about charging a cell phone in
a minute, and a battery that can handle daily charging for decades.
The battery has an aluminum
anode and graphite cathode in a liquid salt electrolyte. It still needs some
work, but shows great potential, its inventors say.
And it’s not just for small
electronics. “The grid needs a battery with a long cycle life that can rapidly
store and release energy. Our latest unpublished data suggest that an aluminum
battery can be recharged tens of thousands of times,” said Stanford chemistry
professor Hongjie Dai.
But this isn’t to say that
all the research is on new battery technologies. There’s also still a lot of
work underway on improving existing batteries. As an example, South Korean researchers are reporting on a new lithium-ion design that improves its
performance while reducing the problem of overheating.
And MIT researchers say they’ve
developed a way to cut in half the cost of building lithium-ion batteries.
That, and they work better, too.
Furthermore, there’s research
underway in figuring out how to improve the amount of energy lost in charging
and discharging a battery. Generally, you can lose 20 percent or more of the energy
it takes to charge a battery when to draw that energy back out.
Researchers at Case Western
Reserve University say they’ve adapted solar cells to dramatically increase that
efficiency. They wired four perovskite solar cells in series and were able to
charge a lithium-ion battery with 7.8 percent loss—the best performance seen to
date, they say.
Here is the paper, but it’s a
little technical. The Science Daily report on the work is here.
Perovskite solar cells are
comparatively new on the solar scene. They can be manufactured inexpensively,
and reportedly can convert into electricity a larger proportion of the sun’s
light than other solar panels.
A lot of folks have wondered
whether supercapacitors can be adapted to provide long-term energy storage.
Supercapacitors are units that can store a lot of power, but they discharge
almost instantaneously. Great for a sudden need for power—like when a motor
starts up—but less useful as a continuing source of energy.
But there are a lot of
applications for bursts of energy that are inefficiently met with standard
batteries. Researchers at Department of Energy's Oak Ridge National Laboratory
and Drexel University looked at new ways to use water materials—specifically old
tires—in the manufacture of supercapacitors.
The point here has not been
to cover the universe of battery innovation, but to show that there’s a lot
going on. Some of this stuff may not pan out, but a lot of it will, and it will
change the energy landscape.
Some of these technologies may end up in our phones, in our cars, in our houses, out on our utility grids--and maybe even in places where we've never imagined a role for energy storage.
© Jan TenBruggencate 2015
Gr8 update, bruddah!
ReplyDeleteU rock!
:) Love the title - especially with the record for lithium storage.
ReplyDeleteSounds like a very bright future. Meanwhile, back at the ranch.....
ReplyDelete