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by a1371
388 days ago
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I'm not sure what's forbidden here. You don't need 100% relative humidity to grab water from the air in fact in any wood has a moisture content that in equilibrium is in relation to the air moisture content. The moisture diffuses into every material and evaporates based on where it finds less vapor pressure. That's why you may have dry lips at 40% RH versus moisturized lips at 70% RH. What you're referring to is condensation and is caused by air oversaturation due to a temperature drop which doesn't seem to be the case here. Theoretically speaking, you can have a material that somehow absorbs high moisture from the air but has microscale properties that promote creation of droplets then somehow these droplets are separated from the rest of the air (with something like a smart vapor retarder, a passive material) and the water gets harvested. |
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Forming a convex surface, on the other hand, requires an at least slightly hydrophobic material and produces a positive internal pressure. This is a key difference, because condensation into a hydrophilic pore is favorable in terms of free energy, while condensing onto a hydrophobic surface is unfavorable (unless you have a supersaturated vapor).
> Theoretically speaking, you can have a material that somehow absorbs high moisture from the air but has microscale properties that promote creation of droplets then somehow these droplets are separated from the rest of the air
That "somehow" is what makes the paper's claims impossible. The water condenses spontaneously into the pore because it thereby lowers its free energy. Extruding it onto the surface is then even more unfavorable than direct condensation. Unfortunately, no passive system can achieve this feat, no matter how cleverly nanostructured, as it would go against the arrow of increasing entropy. You need an external energy source to drive that process.
1. https://en.wikipedia.org/wiki/Capillary_condensation