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A new technique for electrostatically removing dirt from the surface of solar cells could remove the need to regularly wash them, potentially saving billions of liters of water every year in some of driest regions on Earth, Tim Wogan reported for Chemistry World.
Photo Insert: An illustration of the waterless method to clean dust off of solar panels.
Solar energy is perhaps the most appealing renewable technology as it is widely scalable and is readily available in arid regions that are sparsely populated. However, such regions are often dusty and this can rapidly obscure the surface of a solar cell.
Dust can be removed by regularly pressure-washing the surface, but washing the solar cells accounts for up to 10% of the maintenance costs of a typical solar farm, with enough water used every year worldwide to satisfy the needs of two million people.
Moreover, as the water often has to be shipped in and purified, ‘there is a CO2 footprint associated with the water footprint too’, explains Kripa Varanasi of the Massachusetts Institute of Technology (MIT).
Some solar farms clean by dry scrubbing. This is less effective, however, and abrasion gradually reduces the transparency and therefore the efficiency of the solar cells. Lifting the particles electrostatically is a tantalizing idea that has been implemented on extra-terrestrial rovers.
Unfortunately, these systems, which work by surface charge induction in a non-uniform field, require micro-fabricated electrode arrays either on or inside the surface of the cell, making this difficult to roll out at scale.
Varanasi and colleague Sreedath Panat demonstrate a simpler solution, covering the solar cell with a transparent electrode and causing the particles to become charged by an applied potential. This is unexpected because desert dust largely comprises silica – an insulator that should not become charged by contact with an electrode.
However, the researchers showed that, at humidity above 30%, which even most deserts achieve at nighttime, the particles behaved in tests like steel grains, rather than insulating Teflon particles. They concluded after further tests that, as silica is extremely hydrophilic it becomes surrounded by a shell of conductive water molecules.
The researchers designed a prototype solar cell with a cleaning system comprising a robotic arm swept over the surface of a dust-covered transparent aluminum zinc oxide conductor. When they applied a voltage of 12kV between the two, they observed up to 95% recovery of output power.
Varanasi believes such a system could be retrofitted to existing silicon solar cells and could potentially be integrated into the production of future thin-film solar cells during manufacturing. He estimates the technology could save 80%–90% of the cleaning costs, although they will know more after field trials.
