If the protein can actually supply energy continuously, it has to be maintaining a gradient. Whatever comprises the gradient has to go somewhere when the energy is consumed.
So where does the water go? If the protein eventually becomes full of water, then it's power storage, not generation.
They say it's a "self-maintaining moisture gradient." Obviously, if the moisture gradient remains despite being harvested for energy, it must be driven by some other energy gradient in the environment; but it's possible that the protein conversion to electricity has some benefits that directly harvesting this other gradient would not have.
The article is a bit light on details. It could be bullsh*t. I'm not defending it.
HOWEVER I've been studying biogenesis within c3/c4 plants and there are some fascinating structures inside natural systems. I'm amazed at how little we actually know.
The hot new science trend of 'biomimcry' uses a lot of inspiration from those natural systems - many of the inventions use a combination of hydrophilic and hydrophobic membranes that accept, transform, then excrete the byproducts (almost like a pump).
The membranes themselves are often exotically doped chemicals and/or graphene carbon-nanotube structures which exhibit all sorts of weird nano-scale behaviors that replicate things we take for granted in nature (i.e. did you ever wonder how water gets to the top of a giant redwood without a pump?)
A gradient can be maintained between different layers of a membrane (the recent example of generating current from rainwater used a highly exotic modified form of a FET/BJT as the water oxidized across the metals to collect and transfer a charge as the water moved across it).
If the end by-product is dissipated with diffusion (or in this case a water condensate and gravity) it is possible to create structures that use that surface tension of water to move against gravity pulling the moisture through it.
Additionally are algae's (proteins?) which can perform photosynthesis with both sunlight and moonlight, and others that work in complete darkness and even generate their own light (bio-luminescence) or heat.
There is a lot of 'free potential' within entropy so pulling a few mV out of the chaos isn't' inconceivable.
An old scout trick to get water out of the air is to use a plastic sheet to make a "solar still", moisture condenses on the underside of the sheet and is collected in a cup. The environment provides the energy and moisture.
Absolutely yes. Dehumidification typically involves a full refrigeration cycle. It's like leaving a refrigerator running with the doors wide open, the only purpose being to drain out the few drops of water that drip off the condenser coil every minute. Not a very productive process.
And any process which provides energy-free dehumification would also have the secondary (or primary) benefit of providing energy-free freshwater.
I'd imagine they've thought of both the above applications, and their protein nanowires aren't suitable.
re, we fabricated an electric generator from a thin film of protein
nanowires that produces continuous current for at least 20 h before self-
recharging, with a more than two orders of " thanks 4link. Recharging? Drying?
dimensions, stacking thin-film
devices in the vertical direction with a 1/1 film/airgap ratio can lead to a
practical volumetric power density of more than 1 kW m−3 (Supplemen-
tary Fig. 24), potentially outperforming solar cells,
The title of the paper is misleading -- it's not generating energy from ambient humidity, but from sitting across a humidity gradient (i.e. sitting in a bucket of water on one end).
Still a really cool advancement, but not some magical de-humidification technology.
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[ 3.3 ms ] story [ 46.7 ms ] threadSo where does the water go? If the protein eventually becomes full of water, then it's power storage, not generation.
HOWEVER I've been studying biogenesis within c3/c4 plants and there are some fascinating structures inside natural systems. I'm amazed at how little we actually know.
The hot new science trend of 'biomimcry' uses a lot of inspiration from those natural systems - many of the inventions use a combination of hydrophilic and hydrophobic membranes that accept, transform, then excrete the byproducts (almost like a pump).
The membranes themselves are often exotically doped chemicals and/or graphene carbon-nanotube structures which exhibit all sorts of weird nano-scale behaviors that replicate things we take for granted in nature (i.e. did you ever wonder how water gets to the top of a giant redwood without a pump?)
A gradient can be maintained between different layers of a membrane (the recent example of generating current from rainwater used a highly exotic modified form of a FET/BJT as the water oxidized across the metals to collect and transfer a charge as the water moved across it).
If the end by-product is dissipated with diffusion (or in this case a water condensate and gravity) it is possible to create structures that use that surface tension of water to move against gravity pulling the moisture through it.
Additionally are algae's (proteins?) which can perform photosynthesis with both sunlight and moonlight, and others that work in complete darkness and even generate their own light (bio-luminescence) or heat.
There is a lot of 'free potential' within entropy so pulling a few mV out of the chaos isn't' inconceivable.
You usually have to expend energy to get water out of the air, no?
I'm sure the researchers have thought of this, but it wasn't in the abstract.
And any process which provides energy-free dehumification would also have the secondary (or primary) benefit of providing energy-free freshwater.
I'd imagine they've thought of both the above applications, and their protein nanowires aren't suitable.
Still a really cool advancement, but not some magical de-humidification technology.