Iceland’s Glaciers – 360 | Into Water

In the first of National Geographic’s “Into Water” 360 series, travel by air, boat and jeep through the rugged Icelandic countryside with geographer and glaciologist Dr. M Jackson. She has spent the last decade documenting the incredible physical and cultural changes of the island nation as it experiences an unprecedented melting of its iconic ice. “Into Water: Iceland” is the first stop on an around the world 360 tour that documents the work of female Explorers who’ve dedicated their careers to water-related issues.

Can Sea Water Desalination Save The World?

Today, one out of three people don’t have access to safe drinking water. And that’s the result of many things, but one of them is that 96.5% of that water is found in our oceans. It’s saturated with salt, and undrinkable. Most of the freshwater is locked away in glaciers or deep underground. Less than one percent of it is available to us. So why can’t we just take all that seawater, filter out the salt, and have a nearly unlimited supply of clean, drinkable water?

Transforming Air Into Pure Drinking Water Is Finally Possible, Here’s How

Climate change threatens to make dry regions even drier, so scientists at UC Berkeley created a device to make water out of thin air.

At least one hundred million people live in desert regions around the world according to the UN, and they survive off of less than 25 cm of rainfall each year, and for many, even that minuscule water supply is under threat as the climate crisis is making dry areas even drier.
So scientists at UC Berkeley have been experimenting with materials that can pull drinking water out of thin air.

That’s right, right out of thin air.

A chemist at the University of California, Berkeley reported that he and his colleagues have created a solar-powered device that could provide water to millions living in water-stressed regions.

At the device’s heart is a porous crystalline material, known as a metal-organic framework (MOF), that acts like a sponge: It sucks water vapor out of air, even in the desert, and then releases it as liquid water.

A single gram of an MOF can have the surface area of a football field, and depending on the metal and organic molecules they’re made of, MOFs can be tailored to capture various different things in their pores. For example, an MOF could have the ability to capture CO2 and turn it into the fuel methanol, or neutralizing nerve agents like sarin gas. The function the Berkeley scientists used their MOF for was extracting water vapor that’s present in the air.

The lead researcher behind the device started a private company called Water Harvesting.

The company’s plan is to launch a microwave-sized device that can supply 2 adults with enough water for their daily hydration and cooking needs. Eventually the research team envisions a harvester device big enough to supply a small village. If the devices end up being affordable, safe, and reliable enough, these metal-organic frameworks have the potential to turn even the driest desert into an oasis.