Everything Everywhere Daily: History, Science, Geography & More - Desalination
Episode Date: June 17, 2025Seventy percent of the Earth’s surface is covered with water… and the vast majority of it is useless for consumption or agriculture. This problem has been known for thousands of years, and for ...thousands of years, humans have recognized that it is possible to turn seawater into drinking water; it was just difficult to do so. In the last few decades, however, the ability to get clean drinking water from the sea has gotten easier and might get even easier still. Learn more about desalination, how it works, and how it has evolved on this episode of Everything Everywhere Daily. ***5th Anniversary Celebration RSVP*** Sponsors Newspapers.com Get 20% off your subscription to Newspapers.com Mint Mobile Cut your wireless bill to 15 bucks a month at mintmobile.com/eed Quince Go to quince.com/daily for 365-day returns, plus free shipping on your order! Stitch Fix Go to stitchfix.com/everywhere to have a stylist help you look your best Stash Go to get.stash.com/EVERYTHING to see how you can receive $25 towards your first stock purchase and to view important disclosures. Subscribe to the podcast! https://everything-everywhere.com/everything-everywhere-daily-podcast/ -------------------------------- Executive Producer: Charles Daniel Associate Producers: Austin Oetken & Cameron Kieffer Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Update your podcast app at newpodcastapps.com Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Facebook Group: https://www.facebook.com/groups/everythingeverywheredaily Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/ Disce aliquid novi cotidie Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
Discussion (0)
70% of the Earth's surface is covered with water, and the vast majority of it is useless for
consumption or agriculture. This problem has been known for thousands of years, and for thousands
of years, humans have recognized that it is possible to turn seawater into drinking water,
it was just difficult to do so. But in the last few decades, the ability to get clean drinking
water from the sea has gotten easier, and it might get even easier still.
Learn more about desalination, how it works, and how it works.
how it's evolved on this episode of Everything Everywhere Daily.
What if your perceptions about the past were wrong?
ThruLine is a podcast that takes you back in time to uncover the parts of the story that may
have gone unnoticed.
It effectively turned day into night.
And how it shaped the world now.
Time travel with us every week on the ThruLine podcast from NPR.
I'm sure most of us have had the exact same thought when we've heard.
about the crisis of fresh water that afflicts some parts of the world.
Why don't we just crank up some desalination plants and get some fresh water from the sea?
Problem solved.
In theory, that isn't wrong.
However, as I often like to say on this show, there's more to it than that.
Removing salt from seawater isn't conceptually difficult.
However, it becomes very difficult to do at scale.
The story of desalination actually goes back thousands of years.
The story begins with our early.
ancestors who likely observed that when seawater evaporated in tidal pools, it left behind salt
crystals. This natural phenomenon planted the seed of an idea. What if we could capture the pure
water that escaped as vapor? The ancient Greeks were among the first to really think about this
observation. Around the 4th century BC, Aristotle wrote about distillation, describing how seawater
could be heated to produce vapor that, when cooled, would condense into fresh water. Ancient sailors
discovered that they could boil seawater in pots and capture the steam on cloth or metal surfaces.
When the steam condensed, they had drinking water. This was labor-intensive, fuel-intensive,
and didn't produce very much water, but it could mean the difference between life or death on long
voyages. During the medieval period, Islamic scholars and alchemists significantly advanced
distillation techniques. They weren't primarily focused on desalination, but their work on
perfecting distillation apparatus laid crucial groundwork. These innovations would later
prove essential for scaling up seawater treatment. As European exploration expanded in the 15th and
16th centuries, the need for reliable freshwater at sea became critical. Ships began carrying
primitive solar stills, essentially glass-covered boxes where seawater would evaporate under the sun's heat
and condense onto the cooler glass surface. Again, this could only produce a few cups of water a day,
but it was better than nothing. The first known land-based seawater distillation plant was established
by Spanish forces in Tunisia in 1560, who were being besieged by the Ottoman Empire.
Facing acute shortages of potable water while stationed near the arid coast,
Spanish engineers constructed a rudimentary yet effective desalination apparatus on shore.
The plant boiled seawater and metal vessels over open fires
and captured the steam and rudimentary condensation coils to collect fresh water.
In the 17th century, Robert Boyle and other early chemists began experimenting with distillation more formally,
improving the theoretical understanding of phase change and condensation.
However, the practicality of desalination was limited by the energy demands and the complexity of the equipment.
The 19th century marked a huge turning point.
Steam engines weren't just revolutionizing transportation and manufacturing.
They were making large-scale desalination theoretically possible.
Ships could now dedicate steam power specifically to distillation, producing more fresh water than ever before.
The first industrial land-based desalination plant was built in 1869 in Aden in what is today Yemen by the British,
who needed to supply fresh water to ships traveling to India.
This plant used steam distillation and could produce about 5,000 gallons a day,
a significant achievement for its time, though tiny by today's standards.
Both World Wars accelerated desalination research.
Submarines needed compact efficient systems to produce drinking water during their long underwater voyages.
The military's willingness to invest heavily in research, combined with the life or death necessity
of the issue, pushed the technology forward rapidly.
During this period, engineers began experimenting with different approaches beyond simple distillation.
They developed multi-stage flash distillation, where water is heated under pressure
and then released into chambers at lower pressure, causing it to flash into steam.
This was more efficient than single boiling because it could reuse heat energy multiple times.
In the 1950s and 60s, multi-stage flash distillation became the dominant desalination method,
especially in oil-rich but water-poor nations like Saudi Arabia, Kuwait, and the United Arab Emirates.
These countries had access to cheap fossil fuels and could build large-scale plants along the coast.
Everything I have described up until this point, from ancient times to about the mid-20th century,
are all using variations of what is called thermal desalination,
whether it's simple condensation, distilling, or flash distillation,
all of these involve the use of heat to separate water from salt.
Thermal desalination is something that you could do in your kitchen stove,
although it isn't necessarily that efficient.
It was around the 1960s that a second type of desalination became practical.
Generally, this category is referred to as membrane desalination.
Scientists discovered that certain materials could act as selective barriers
allowing water molecules to pass through while blocking salt ions.
This led to the development of reverse osmosis,
a process fundamentally different from distillation.
In 1965, the first reverse osmosis membranes were developed at UCLA
by Sidney Loeb and Srinivasa Shuri-Rajan.
These membranes use semi-perbiumal materials that could separate water from dissolved salts under pressure,
a radically different and more energy-efficient approach than distillation.
To describe how reverse osmosis works, I have to explain a few things.
First, a semi-permeable membrane has microscopic pores typically around 0.001 microns wide that allow
water molecules to pass but block dissolve salts, bacteria, and larger molecules.
Second, to know how reverse osmosis works, you need to know how osmosis works.
Let's say you have a container with a semi-permeable membrane.
separating it in two. On one side you put seawater and on the other side you have fresh water.
What would happen? Via osmosis, water from the freshwater side will migrate to the saltwater side.
This is because the salinity levels on the two sides are out of balance, and water will move to the
salty side to dilute it to put the two sides in equilibrium. The water has to move because the
salt can't. Osmosis, however, is the exact opposite of what you want.
if you want to make fresh water out of seawater.
And this is where reverse osmosis comes in.
In reverse osmosis, you put pressure on the salty side
to push water across the semi-permeable membrane
to separate it from the salt in the seawater.
And this isn't just dumping water on a membrane
to filter out the salt like you would use cheesecloth
to filter out particulate matter.
To get the water through the semi-permeable membrane,
you need pressure.
A lot of pressure.
Creating that much pressure takes a lot of energy. It's much less energy than thermal desalination,
but it still takes energy. From the 1980s onward, rapid improvements in membrane technology,
particular polyamide composite membranes, greatly increased the efficiency and viability of
reverse osmosis. These membranes can operate at lower pressure, resist fouling, and recover
more fresh water from input seawater. Reverse osmosis became the dominant distillation method
globally by the early 2000s.
Large-scale reverse osmosis plants have been constructed in Spain, Israel, Australia, Singapore,
Chile, and the United States, most notably in California and Texas.
Israel in particular became a global leader, utilizing reverse osmosis to supply over 60% of its
domestic fresh water by the 2010s.
Today, reverse osmosis filters are constructed like a paper towel roll.
Instead of paper towels, there are layers and layers of membranes.
High-pressure seawater is on the outside of the layers, and in the core is a pipe where all the fresh water flows.
The average pressure used in modern reverse osmosis systems is about 55 to 70 bar, or 800 to 1,000 pounds per square inch.
Today, there are around 21,000 seawater distillation facilities around the world, spanning approximately 150 to 170 countries.
These plants produce around 100 million cubic meters per day of fresh water,
which translates to about 26 billion gallons or almost a hundred billion liters of water.
That's a lot of water, but it's only a fraction of the total water used by humans every day.
So what would be necessary to increase the amount of desalinated water produced on the planet?
Well, the biggest thing would be to devote significantly more energy.
energy to it. There has been talk of building nuclear reactors, especially dedicated to desalination.
Likewise, there's been talk of fields of solar panels in the deserts and equatorial reasons,
which would be used for running desalination facilities. Passive thermal systems have also
been proposed, which would be giant glass domes in the desert, where salt water could evaporate,
condense on the glass, and then be collected. Basically, just using current technology, the more energy
we throw at the problem the more desalinated water we can get.
However, there are other new methods that are promising.
One solution would be to just make better membranes.
Graphene-based membranes represent a cutting-edge development in desalination technology,
offering the potential for faster, more energy-efficient water purification.
These membranes are typically made from graphene oxide,
or single-layer perforated graphene sheets, engineered with nanopon,
pores precisely sized to allow water molecules to pass while blocking salts and other contaminants.
Because graphene is just one atom thick, water can flow through it orders of magnitude faster
than through traditional polymer membranes used in reverse osmosis.
This ultra-thin structure could drastically reduce the energy required to pressurize water,
the major cost factor in desalination.
Additionally, graphene membranes show high resistance to fouling chemical degradation, increasing
their durability and reducing maintenance. Another proposal, and one that I personally think is
rather brilliant, is to use the natural high pressures of the ocean floor. If you put a reverse
osmosis filter far enough below the surface of the ocean, you can reach pressures that are the same
as those required for reverse osmosis systems. And do you know what else is on the bottom of the
ocean? Seawater. Of course, there needs to be a pressure difference to move the freshwater along.
but you can create that by creating suction to make a pressure differential.
The amount of energy needed to create suction to suck high-pressure water out
is much less than the energy required to create high-pressure water on land.
To be sure, this would reduce the amount of energy required,
but it would also create its own headaches,
including performing maintenance on filters sitting at the bottom of the ocean floor.
There are other potential technologies as well that could be used,
including nanofilters and forward osmosis.
The ability to create fresh water from seawater is a vital technology in the 21st century.
Depending on where you live, it might not be something that you ever encounter.
However, millions of people every day rely on it to get water for drinking, bathing, and washing.
Without it, ships and submarines would find it much more difficult to spend lengthy amounts of time at sea.
And assuming trends continue, the amount of usable water that humanity gets from the sea
should only be increasing for years to come.
The executive producer of Everything Everywhere Daily is Charles Daniel.
The associate producers are Austin Oakden and Cameron Kiefer.
I want to thank everyone who supports the show over on Patreon.
Your support helps make this podcast possible.
I'd also like to thank all the members of the Everything Everywhere community
who are active on the Facebook group and the Discord server.
If you'd like to join in the discussion, there are links to both in the show notes.
And as always, if you leave a review or send me a boostagram, you two can have it read on the show.
Thank you.