Ecole Polytechnique Fédérale de Lausanne
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| Credit: Kevin Sivula (EPFL) / Creative Commons Attribution 4.0 International License |
Storing solar energy as hydrogen is a promising way for
developing comprehensive renewable energy systems. To accomplish this,
traditional solar panels can be used to generate an electrical current that
splits water molecules into oxygen and hydrogen, the latter being considered a
form of solar fuel.
However, the cost of producing efficient solar panels makes
water-splitting technologies too expensive to commercialize. EPFL scientists
have now developed a simple, unconventional method to fabricate high-quality,
efficient solar panels for direct solar hydrogen production with low cost. The
work is published in Nature Communications.
Many different materials have been considered for use in direct
solar-to-hydrogen conversion technologies but "2-D materials" have
recently been identified as promising candidates. In general these
materials--which famously include graphene--have extraordinary electronic
properties.
Kevin Sivula and colleagues at EPFL addressed this problem with
an innovative and cheap method that uses the boundary between two non-mixing
liquids. The researchers focused on one of the best 2-D materials for solar
water splitting, called "tungsten diselenide." Past studies have
shown that this material has a great efficiency for converting solar energy
directly into hydrogen fuel while also being highly stable.
Before making a thin film of it, the scientists first had to
achieve an even dispersion of the material. To do this, they mixed the tungsten
diselenide powder with a liquid solvent using sonic vibrations to
"exfoliate" it into thin, 2-D flakes, and then added special
chemicals to stabilize the mix. Developed by Sivula's lab (2014), this
technique produces an even dispersion of the flakes that is similar to an ink
or a paint.
The researchers then used an out-of-the-box innovation to
produce high-quality thin films: they injected the tungsten diselenide ink at
the boundary between two liquids that do not mix. Exploiting this oil-and-water
effect, they used the interface of the two liquids as a "rolling pin"
that forced the 2-D flakes to form an even and high-quality thin film with
minimal clumping and restacking. The liquids were then carefully removed and
the thin film was transferred to a flexible plastic support, which is much less
expensive than a traditional solar panel.
The thin film produced like this was tested and found to be
superior in efficiency to films made with the same material but using other
comparable methods. At this proof-of-concept stage, the solar-to-hydrogen
conversion efficiency was around 1%--already a vast improvement over thin films
prepared by other methods, and with considerable potential for higher
efficiencies in the future.
More importantly, this liquid-liquid method can be scaled up on
a commercial level. "It is suitable for rapid and large-area roll-to-roll
processing," says Kevin Sivula. "Considering the stability of these
materials and the comparative ease of our deposition method, this represents an
important advance towards economical solar-to-fuel energy conversion."
This work was funded by the Swiss Competence Centers for Energy
Research (SCCER Heat and Electricity Storage) and the European Commission's
Framework Project 7 (FP7) through a Marie-Curie Intra-European Fellowship
(COCHALPEC).
