Level 1 - Absolute Beginner
Scientists have built a new machine that uses sunlight to make clean water from seawater. Seawater has too much salt for people to drink. The machine removes the salt.
The machine also collects lithium from the salty water that is left over. Lithium is used to make batteries for phones and electric cars. This means the machine makes two useful things at once.
The scientists are from the University of Rochester. They published their work in a science journal. This new system could help places where there is not enough clean water.
- scientist
- a person who studies the natural world through experiments and observation
- seawater
- water from the ocean, which contains salt and cannot be drunk directly
- salt
- a white mineral found in seawater that makes it unsuitable for drinking
- sunlight
- light that comes from the sun
- lithium
- a light metal used to make rechargeable batteries
- battery
- a device that stores electricity and releases it to power things
- journal
- a magazine where scientists publish new research for others to read
- clean water
- water that is safe and suitable for drinking
Level 2 - Elementary
Scientists at the University of Rochester have created a solar desalination system that can turn seawater into fresh drinking water using only sunlight. Desalination means removing salt from water. Most desalination systems use a lot of electricity and produce a thick salty waste called brine that is hard to dispose of.
The new system uses a special surface made by laser technology. The surface has tiny patterns that pull water and salt to the edges of the panel. This stops salt from building up in the middle, which normally breaks most desalination devices. The researchers called this property 'superwicking'.
As the salt moves to the edges, it concentrates enough for the scientists to extract lithium from it. Lithium is a key material in batteries for electric cars and smartphones. The team published their results on May 30, 2026 in a journal called Light: Science and Applications.
- desalination
- the process of removing salt from seawater to make it drinkable
- brine
- very salty water left over after desalination
- laser
- a device that produces a very powerful, narrow beam of light
- superwicking
- the ability of a surface to move liquid along it very quickly by capillary action
- extract
- to remove a substance from a mixture
- concentrate
- to increase the amount of a substance in a smaller volume
- dispose of
- to get rid of something, especially waste
- property
- a quality or characteristic belonging to something
Level 3 - Intermediate
A research team at the University of Rochester has engineered a passive solar desalination system that simultaneously produces potable water and recovers battery-grade lithium from seawater. Published May 30, 2026 in Light: Science and Applications, the study presents a solution to one of the oldest problems in desalination technology: salt crystallization on the evaporator surface, which rapidly degrades performance and shortens device lifespans.
The team's innovation is a superwicking surface created by irradiating a titanium substrate with femtosecond laser pulses. The ablation process carves a hierarchical network of micro- and nanostructures that exploit capillary pressure to transport the salt-rich boundary layer away from the hot central zone toward cooler peripheral channels. There, lithium ions are selectively trapped by sodium titanate nanoparticles, achieving approximately 50 percent recovery of the lithium dissolved in typical seawater concentrations.
Beyond clean water production, the system's economic case rests heavily on that lithium recovery. Lithium prices have remained elevated since the electric vehicle boom accelerated demand far ahead of mining supply. The Rochester system's solar-only operation and zero liquid discharge profile make it particularly attractive for remote coastal communities and island nations that currently rely on expensive diesel-powered desalination plants. The researchers estimate that, scaled to a one-square-meter panel, the system could produce five liters of fresh water per hour under peak solar conditions.
- potable
- safe and clean enough for humans to drink
- crystallization
- the process by which a dissolved substance forms solid crystals as liquid evaporates
- femtosecond laser
- an ultra-short pulse laser that fires pulses lasting one quadrillionth of a second
- ablation
- the removal of material from a surface using a laser or other energy source
- capillary pressure
- the force that causes liquid to flow through narrow spaces or against gravity
- nanoparticles
- extremely small particles, typically between 1 and 100 nanometers in size
- zero liquid discharge
- a system that produces no wastewater, recovering all water and concentrating all dissolved solids
- substrate
- a base layer of material on which processes or reactions take place
Level 4 - Advanced
A multidisciplinary team at the University of Rochester has reported, in Light: Science and Applications (May 30, 2026), a passive solar desalination architecture that resolves the long-intractable problem of salt fouling while adding a secondary revenue stream: battery-grade lithium recovery. Conventional solar evaporators fail within days because dissolved salts nucleate and crystallize on the heated surface, creating an insulating crust that halts evaporation. The Rochester team circumvents this by structuring the evaporator surface at micro- and nanoscale resolution using femtosecond laser ablation, a non-thermal process that preserves the underlying substrate while generating a hierarchical wicking topology.
The resulting superwicking surface harnesses anisotropic capillary pressure gradients to actively convect the salt-enriched boundary layer from the central hot zone toward peripheral cooler channels, a process the team terms 'salt steering.' At the periphery, a bed of H2Ti3O7 nanoparticles exploits the material's well-documented selectivity for Li+ ions over Na+, Mg2+, and K+, achieving a recovery rate of approximately 50 percent from typical open-ocean concentrations of 0.2 milligrams per liter. The selectivity arises because the titanate's tunnel structure is sterically complementary to the hydrated ionic radius of lithium, excluding larger competing cations.
The system's techno-economic profile is compelling at two scales. At the household level, a one-square-meter panel can yield five liters per hour of potable water under peak solar irradiance, sufficient for daily drinking-water needs in arid coastal regions where piped supply is unreliable. At the industrial scale, the lithium recovery function represents a margin enhancer that could offset capital costs within three to five years, depending on prevailing lithium carbonate spot prices. The zero-liquid-discharge architecture also sidesteps the regulatory and ecological concerns that have stalled conventional concentrate-disposal from large reverse-osmosis plants, particularly in enclosed seas such as the Arabian Gulf and the Mediterranean.
- fouling
- the gradual blockage or degradation of a surface or membrane by deposited material
- anisotropic
- having different properties in different directions, enabling directional fluid transport
- convect
- to transfer heat or material through the movement of a fluid driven by a gradient
- sterically complementary
- fitting together because the three-dimensional shape of one molecule matches the cavity of another
- cation
- a positively charged ion, such as Li+, Na+, or K+
- irradiance
- the power of solar radiation received per unit area, typically measured in watts per square meter
- techno-economic
- relating to the combined technical performance and economic viability of a system
