The team designed a two-step cooling and regeneration system, with the cooling step based upon the fact that dissolving certain common salts in water absorbs energy, which rapidly cools the water. After comparing a range of salts, ammonium nitrate (NH4NO3) proved to be the standout performer, with a cooling power more than four times greater than its closest competitor, ammonium chloride (NH4Cl). The ammonium nitrate salt's exceptional cooling power can be attributed to its high solubility.

"NH4NO3's solubility reached 208 grams per 100 grams of water, whereas the other salts were generally below 100 grams," Wenbin said. "This salt's other advantage is that it is very cheap and already widely used as fertilizer."

The system has good potential for food storage applications, the team showed. When the salt was gradually dissolved in water in a metal cup placed inside a polystyrene foam box, the temperature of the cup fell from room temperature to around 3.6 degrees Celsius and remained below 15 degrees Celsius for more than 15 hours.

Once the salt solution reached room temperature, the team used solar energy to evaporate the water using a bespoke, cup-shaped 3D solar regenerator. The cup was made from a material designed to absorb as much of the solar spectrum as possible. As the water evaporated, the NH4NO3 crystals grew over the cup's outer wall.

Wenbin said, "The crystallized salt can be collected automatically as the salt drops off due to gravity."

Once collected, the salt effectively represents a stored form of solar energy, ready to be reused for cooling again when required.

Related links:

• From the journal, Energy & Environmental Science — Conversion and storage of solar energy for cooling
• KAUST Discovery