This is actually promising. Been able to simply dump incoming heat is seriously desirable. Just as obviously this material demands no meaningful ongoing inputs. You put it on your roof and forget about it.
We have spent a low of effort simply trying to convert incoming radiation into power with no practical result. Just dumping it back out is simple enough and naturally cheap once you have the right tool.
all good.
.
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A Cheap New Metamaterial Offers Air Conditioning Without Air Conditioners
Feb 9 2017, 11:00am
A major advance in daytime radiative cooling.
https://motherboard.vice.com/en_us/article/a-cheap-new-metamaterial-offers-air-conditioning-without-air-conditioners
The past decade has seen a recasting of air conditioning as an
ironic villain. This technology that we use to live in defiance of heat
is itself, as a nearly unparalleled energy hog, contributing to the very
heat it exists to dispel. We turn up the AC and the climate responds. According
to the United States Department of Energy, air conditioning in the
United States accounts for 117 million metric tons of carbon dioxide
released into the atmosphere every year.
As described
in the current issue of Science, researchers at the University of
Colorado and the University of Wyoming have developed a new metamaterial
(a material engineered to have extraordinary properties) that offers at
least a partial potential solution in the form of daytime radiative
cooling. That's the process by which incoming thermal energy from the
Sun is exchanged for outgoing energy in the form of infrared radiation.
While
efficient nighttime radiative cooling systems are pretty reasonable,
achieving the same thing during daylight hours has been hampered by a
fundamental problem: Absorbing even just a few percent of the incoming
radiation from the Sun easily washes away any potential cooling
benefits. What's needed is a material that strongly emits infrared
radiation, but just barely absorbs energy from the Sun.
Materials scientists have accomplished
this previously by using very complicated and difficult-to-produce
nanomaterials. As the current paper explains, these prior attempts are
all hampered by the fact that they require exotic and impractical
fabrication techniques. The challenge here was to make something that
could actually be scaled to real-world use.
The resulting
material is composed of a layer of visibly transparent polymers randomly
embedded with tiny spheres of glass and then covered over by a thin
layer of silver. Basically, incoming light of many different wavelengths
gets caught up in and then reemitted by the spheres. The randomization
of these spheres is part of what accounts for the wide range (96
percent) of reflectivity across the spectrum of sunlight.
The
researchers behind the current paper tested out their new material in a
couple of different ways. In one, it was stretched out over part of a
styrofoam cooler that was kept at a constant temperature by an attached
heater. Here, cooling capacity could be measured by the amount of
heating power was required to maintain this temperature across a long
timespan. In a second experiment, the material was used to cool water,
which functioned as a cooling storage medium—like a battery for
coldness.
It's still unclear as to how the material will fare in
terms of reliability and lifetime for practical outdoor applications,
but a world where we don't have to cart around energy-guzzling
appliances to guarantee ourselves fake microclimates doesn't seem that
far away.
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