Make the Drought Evaporate!
~ desalinate with <5% the energy & equipment ~ ---cross-post!
TL;DR — We need to stop droughts, especially as climate change makes them worse. Desalination is nice, capturing clean water from the sea, yet it requires expensive equipment and lots and lots of energy. We can, instead, accelerate evaporation OUT into the air above our heads! We won’t be ‘capturing’ that clean water — it just rains-down miles away. Perfect, because we don’t need pipes and pumps to transport it! Using this sort of design, we can end droughts and re-take the land captured by deserts in recent decades, cheaply and quickly.
The Concept
Imagine you have a bowl of salty sea water, with a tiny hole at the bottom. The sea water is slowly dribbling out of that hole, into another bowl beneath, to then get pumped back up to the top. At that dribbling spout, you hang a loose, fuzzy length of yarn, straight down. The water is held against that yarn by surface tension, scuttling down along its surface.
As the wind blows past your wet-yarn-wick, it will cause evaporation from that surface, adding humidity to the air, to come back down as rain further downwind. (Place the evaporators geographically so that the wind carries the water to the general spot you plan to use.) With wide troughs, thousands of yarns packed per square yard, stacked a dozen feet high in layers, you can pump vast amounts of water into the air.
The cost of pumping sea water up onto those troughs, only a few dozen meters above sea-level, is less than 1 Megajoule per ton of water. A Megajoule generated on-site from solar, only pumping when the sun shines, costs about 1 or 2 cents, for a ton of water to evaporate and return as rain on farms and snowpack in the mountains. For anyone in Ag, this translates to “$12 per acre-foot of irrigation, with no pumping or well-drilling, maintenance, or ditches… because it just rains.” That sounds darn good to me!
Compare that to the top-of-the-line desalination plants, spending 10 to 20 Megajoules per ton of fresh water produced! If you want to irrigate with that, you need to pump it to the site, with the associated barrier to entry and lag to scaling, maintenance and risk, while the water itself still costs you $240 per acre-foot! Some regions of California have seen peak prices at $2,000 an acre-foot, which is crippling. At $12 a pop, we can get green again — in flora and finances.
Getting into Details
Salt, first — as you evaporate and regurgitate the water in those troughs, it becomes brine, and you pump that out. It’ll only be a fraction of the original volume, and it’ll be chock-full of lithium, magnesium, and potassium, so you might as well make money selling those to make batteries and feed chemical industries. The sodium salt, unfortunately, must be gently dripped back across the wide ocean, OR we can just pile it up to make a giant salt pyramid somewhere nearby. I favor the latter option, because it’s much cheaper and it would still take ages to accumulate a pyramid that would be so large as to be an ‘obstruction’ — plus, the ocean really won’t notice the salt-loss at all, being miles deep. It’d also be rad to ski down and take four-wheelers up it — there are tourist revenue streams for such a unique oddity!
Coastline, next — you do need to pump the sea-water short distances, and up only short elevations, to make it cheap. So, coastlines would need tall, layered racks of troughs, stretching inland as far as elevation allows, to spread water deep to the continent. Another option, with a higher capital cost and maintenance, yet which would allow you to use this option in cases where the coastline is too steep or precious to locals: buoys floating just off-shore, where the winds are still strong!
Adding to the coastline problems: you must pick coasts where the winds pull from the sea into the dry target-region. California’s central valley is a prime example. So are Libya and Israel, able to water deep into the dry lands. Yet, the regions receiving rain from such coasts are often a different country! That’s the biggest barrier to development, and it will be difficult to get those countries to form a neighborly arrangement, until other countries have demonstrated evaporation’s efficacy and value. Once other successes pile-up, the incentive to stop squabbling becomes larger — in order to cash-in on the opportunity.
Power is an issue, too — the best way to power the evaporators is with solar concentrators along that same coastline. Solar can extract hundreds of watts per square meter, which means you only use a thin ribbon of solar to pump for a wide, many-layered swath of evaporator-troughs and yarns. It’ll be the most expensive capital, yet it’s also a small percentage of the total area and equipment. And, by positioning the solar *up-wind* from the evaporators, you are guaranteed many days of clear skies, without your own clouds disrupting power-supplies!
The Big Picture
If these evaporators desalinate and transport irrigation water dozens of times cheaper, hundreds of miles inland, that makes it worth-while — profitable! — to convert many disregarded dry regions into crop land and pasture. That takes pressure off deforestation, much of which happens for the purpose of grazing lands. The more we green the deserts, the more native land we can return to the biome.
Further, we’ve been losing agricultural land, accelerated especially by desertification. This would reverse that trend in many locations, preserving what we do use. Rains are also acceptable for municipal water supplies, precious in regions without steady fresh-water reserves for drinking. And, the rain’s humidity stabilizes the wild temperature-swings of deserts’ day and night, protecting plants and making the region more comfortable and desirable for people to live there. (aka ‘real estate values’)
There is also a social dividend to the work: being the pioneer of it, as well as sharing rain with your neighbors. It can even be a diplomatic shield: who would attack one so useful, especially when that same diligent rainmaker could turn the water off? Evaporators are worth much more than lettuce!
I don’t know anything about this area, but it sounds like something that I’d expect people have looked at before if it’s so technically simple. Do you have a sense of whether this has been trialed, or why it isn’t already being done at scale?
Whoo. Last cross-post for the night, I think I’ve responded to the major points… and I hope this shows a bit more of the complexity underneath my simplistic presentation!
How quickly it rains down depends on a few factors, and we can tip those in our favor:
--> Humid Rise—humidity (just the h2o molecule) is only 18g/mol, while oxygen molecules are 32g/mol, so humid air is quite buoyant! Especially considering that water vapor reflects heat (infrared) back to the ground, creating a heat bulge beneath it. The result is that, once humidity begins to rise, it naturally pulls air in from all around it, along the ground. It begins to drive convection. Yet! That humid rise is normally billowy and easily dispersed by cross-breezes, which means that the humidity cannot rise high quickly; it mostly travels far overland, or stays in place. Your rain wanders to an unexpected location! We want to form rain clouds nearby, instead, so we need that humidity to rise really high, quickly, without being torn apart by cross-breezes. That’s where the solar concentrators help, with their tall tower at 1200C and radiant, they blast infrared into all the water vapor around them, pummeling a plume high up, carrying that vapor. Up high enough, the air pressure drops, which is key for causing a rapid cooling, and the formation of nice heavy clouds. The faster we take air from the ground up to a few kilometers, the more water it’ll still be holding. [[Only a fraction of one gram per m3 is needed for the thinnest clouds, but we could toss a few grams up and it’ll come down soon. We want the water to rain, evaporate, and rain down again, in as many cycles as it can. That gives plants time to grab it, in numerous locations, as well as time for the ground to catch some.]] When we look at water-demand for plants in the wild vs. water-resilient greenhouses, we can drop water demand ten-fold because nine-tenths of the water was lost in the leaves to evapotranspiration! As a result, if that leaf-sweat keeps rising and falling as rain as it travels further South, then the same bucket of water ends up getting ten times the use (assuming ground water is eventually used, as well).
--> Albedo—the desert rock is pretty bright, so the addition of vegetation and especially any water-bodies (!) will multiply the solar absorption, which will drive that heat-bulge and evaporation for humidity-buoyancy, to help loft water vapor and form clouds. This is how the Amazon does it—most of her clouds are her armpit fog, caused by solar-to-thermal foliage!
--> Vortices—the solar concentrators themselves can be rigged with a few flanges, to nudge their inflowing convection as it quickens toward the center, to spin that up-draft, helping it stay coherent and push higher, for rains nearby. Any Youtube video on Rocket Stoves by Robert Murray-Smith is best for enjoying such a vortex!
--> Swales—I love swales. I’ve been preaching swales since 2010. I heard, almost immediately, when Sepp Holzer started pitching his “crater gardens” … which were dug by an excavator, four feet deep. I was aghast—my favorite swales are micro-swales, a few inches deep, in flakey soils that rain seasonally, to catch it as it dribbles. That’s what they’re doing in the Sahel, south of Sahara, to stop the deserts. By halting the flow of water along the ground, keeping it for seep, roots, and another evaporation, you prolong the residence-time of each ton of water, leading to a greater equilibrium stock—that is, a high normal lake line, because each ton of water rarely ever leaves.
And, as to infrastructure before success—California could probably boost rains enough to help farmers and forests, here, without needing to conquer an entire desert the size of Europe!
Another cross-post from Lesswrong about a detailed example, the entire Sahara:
Thank you for diving into the details with me, and continuing to ask probing questions!
The water brought-in by the Sahara doesn’t depend upon the area of the source; it’s the humidity times the m3 per second arriving. Humidity is low on arrival, reaching only 50% right now in Tunisia, their winter drizzles! The wind speed is roughly 2m/sec coming in from the sea, which is only 172,800m/day of drift. Yet! That sea-breeze is a wall of air a half kilometer high—that is why it can hold quite a bit.
If we need +10% of a 500m tall drift, that’s 50m; if we can use solar concentrators to accelerate convection, we can get away with less. And, we’re allowed to do an initial row that follows the shoreline closely, while a second row is a quarter kilometer inland, running parallel to the shore, where mixing of air lets you add another round of evaporate. So, we could have four rows across the northern edge of the Sahara, each row as thick as it needs to be to hit high humidity, and 10m tall, to send +10% moisture over the entire 9 million km2 of the Sahara.
How much water would we be pumping? The Sahara carries 172,800m/day flow per m2 intake surface x 500m tall x 4,000km coastline at 10g h2o per m3 = 3.5 billion tons per day, a thousand or so dead seas. (About 1.25 Trillion tons a year, enough to cover the 9 Million km2 with 139mm of rain, on average, if it had fallen instead of being sopped-up by adiabatic heat.)
We need 10% of that, or a hundred and eighty dead seas. It seems monstrous, but much of the coastline there is low for miles, so pumping 1 ton to the top of 10m at even just 20% efficiency costs 500kJ. If you want to pump that in a day, using solar, you’ll need 1/4th of a square foot of solar. That 1 ton, if we cross the threshold and it becomes surplus rain, will water 3 square meters their annual budget… and the solar is paying for that amount of irrigation every day; 1,000 m2 of rains from a dinner plate of solar, each year. It’s that energy efficiency, combined with dead simple capital expenditures, which would make something so insane potentially feasible. I’d pick California to try, first!
500kJ per ton, for 350Mil tons per day—that’s 175TJ per day, or 2 GW. That’s a nuclear power plant. To pump enough water, continuously, to irrigate 9 million km2, potentially feeding a billion people, once we dig swales! (Check out Africa’s better-than-trees plan: “Demi-Lune” swales that catch sparse, seasonal rain, to seep into the ground, with minimal tools and labor!)
These details might help see the complexities
[[a cross-post of my comment from the Lesswrong cross-post of the original post, in that thread of comments!]]
Let’s start at a more practical scale: make the Negev Bloom.
The Negev is 12,000 km2, which, if we want grasslands, needs some 300mm extra rain or more each year. That’s 3.6 billion tons per year, or just 10Mt a day. With 20g/m3 humidity, we’ll need passage of 500 billion m3 of air-flow each day. With convection driven by solar concentrators (those same which drive the pumps) to increase wind velocity during the day to 4m/s, across trays stacked 12.5m high, provides 50m3/sec, 4.32 million m3 per day across each meter of intake.
Next, we pump rows inland, as each humid layer rises, to capture drier air as they mix and move-past. Additional solar concentrators power these, and conveniently, the concentrators’ intense heat pushes humid air higher than it would during gentle billowing convection, rising to cool & enter the cloud-cycle faster. We would only be prevented from extending more rows if the elevation rises too high, or we create so much humidity and cloud-cover that our solar concentrators cease. Let’s just say we have four rows.
With 4.32 million m3 per meter of intake width, we’ll need 116,000 meters… that’s only 72 miles. With our four rows, that’s a length of coast 18 miles long. The Gaza Strip is enough to water the Negev.
And, as I mentioned in an earlier response to you, the vast majority of the humidity released by the Persian Gulf, Dead Sea, Red Sea, Mediterranean, is being used to fight-against the immense downdraft of adiabatically-heated and ultra-dry upper atmosphere, which is descending because of the boundary between Hadley and Ferrel cells. So, yes, there are billions of tons of water evaporating, and no rain!
Yet, we know from geological records as recent as 9,000 bc, the Sahara was wet, with vast lakes—because of a slight increase in humidity above the threshold for accumulation. The deserts are not ‘infinitely’ dry, such that all water never results in rain. Rather, they are just below a ‘threshold’, with water added by evaporation in huge amounts, and a slightly huger amount being taken away by adiabatic downdraft. If we add just a portion of humidity, we are doing exactly what occurred across the Sahara repeatedly, and it led to accumulation, because it was enough to cross the desiccation threshold. Our own soil records prove that the desert can be green, with just a little more water than it currently evaporates.
Another wonderful example of “so simple, why didn’t anyone try it before” just this week:
Robert Murray-Smith’s wind generators seem to have a Levelized Cost comparable to the big turbines, yet simple and cheap, redundant:
We have repeated evidence of good designs being ignored for a decade or more; hence the Silicon Valley axiom: “10 years ahead of time is as good as wrong.” Similarly, good designs can be appallingly simple, and go unnoticed—for example, Torggler’s swinging-door design (watch on YouTube; there is no way to explain it properly, because it is so bizarrely simple).
Another example is the original river-clean-up buoy-net system, debuted decades ago, and promptly ignored, despite grabbing all the plastic before it entered the ocean. We continued to hope for ‘something to clean up the plastic’ and grasped, later, at the Ocean Clean-Up guy who gave a TED talk. He got millions of dollars, and eventually he heard about the river-scooping buoy bot, and he began promoting it. Without that TED-talker’s promotion, it’s likely we’d all still not know about the more-effective and simpler and safer river-bot. This happens all the time.
Similarly, in 2007, Leapfrog licensed from Anoto a unique dot-pattern, to print on regular paper (tiny dots, you can’t see) such that an optic on a ‘pen’ could read the coordinates, and use an on-board computer and audio to output based upon what it saw you writing. So, you could draw a drum set, and tap each drum to hear it play. Leapfrog was making kid’s workbooks and tailored software. I told them to put the dots on clear adhesive plastic, to convert any existing computer screen into a touchscreen. I faxed them my details, granted them license (they held all the others, and I didn’t want to compete), and they proceeded to ignore me for six years. Leapfrog spun-off the pen and dots, to Livescribe, who was still stuck on how ‘paper is the answer’. By 2013, they’d licensed my touchscreen to Panasonic, who bottled it up inside their $400 tablet that wowed the Germany Electronics Expo with its artistic precision. Artistic precision you could have had in 2007, and you still can’t, because Panasonic is camping on the license.
Don’t pretend that every simple idea must have already been discovered, or must obviously come into use, if it is known. Human reticence to new ideas is often the bigger barrier.
The primary reason no one already mentioned such a solution is: you can’t capture the water. Just like Tesla’s hope for free energy, rain from the sky is difficult to market. Yet, I propose it for the governments who have viable lands; they would see tax returns which would make it valuable, as long as it rained in some of the desert.
I expect most experts are scared of the political difficulties. Also, many people have been slow to update on the declining costs of solar. I think there’s still significant aversion to big energy-intensive projects. Still, it does seem quite possible that experts are rejecting it for good reasons, and it’s just hard to find descriptions of their analysis.
Highly suggest producing some diagrams