Design
of interface-engineered wood-based CPCMs for solar-thermal energy conversion.
BPNS@MPN drop-cast onto DW aerogels denoted as TBW, which after Ag reduction
and 18-alkyl grafting was denoted as TBAW; the final SA-loaded CPCMs were
denoted as TBAWP. Credit: Advanced Energy Materials (2026). DOI: 10.1002/aenm.70872
While sustainable solar energy can
potentially meet our global power needs, it has one major flaw. When sunlight
disappears, solar panels stop generating electricity. The problem is that while
they do an excellent job of converting light into power, they are not so good
at storing the energy they collect.
One solution is to use materials
known to capture heat and release it later, such as phase change materials
(PCMs). However, these can leak when they melt, struggle to conduct heat
quickly, and catch fire easily. So researchers from China decided on a different
approach, turning wood into a multifunctional solar-thermal energy storage
material, as they detail in a paper published in Advanced Energy Materials.
Reengineering balsa wood
The team redesigned the internal
structure of balsa wood at multiple scales, from nano to micro, to create a
material that absorbs sunlight and stores it as heat for later use. It can also
generate electricity when that stored heat is released through a thermoelectric
device.
They first removed the wood's
natural lignin, which acts as a glue holding the fibers together. This left
behind a porous structure of tiny open channels. Then they coated the inside of
these channels with ultrathin sheets of black phosphorene, which absorbs
sunlight across multiple wavelengths and converts it into heat. However,
phosphorene degrades quickly in the air, so the scientists added a protective
layer of tannic acid and iron ions.
Credit: Advanced Energy Materials (2026). DOI: 10.1002/aenm.70872
The next step was to add silver nanoparticles to help the wood capture
sunlight. Finally, they added a water-repellent layer so the material stays dry
and resists rot in all weather.
Once the balsa wood scaffold was ready, the researchers filled it with a
heat-storing wax called stearic acid. This bio-based phase change material melts and
stores energy when heated and solidifies and releases that energy when cooled.
One reason this wood is so thermally efficient is that heat travels along
the grain rather than across the surface. This means it moves faster toward an
external generator to be turned into power.
Impressive performance
To prove that their innovation works, the team ran several tests. In a
solar simulator, it achieved a photothermal efficiency of 91.27%, meaning
almost all the light hitting it became usable heat. The material also stored
175 kilojoules of energy per kilogram. When connected to a thermoelectric
generator, the modified balsa wood produced up to 0.65 volts.
Beyond energy, it performed well against common hazards that wood
structures face outdoors, such as fire, bacteria, and fungi. "The hybrid coating also greatly improves fire safety by reducing
the HRR and THR by 27.4% and 31.2%, respectively, and it works well against E.
coli and S. aureus," commented the study authors in their paper.
By addressing some of these issues, the team is moving closer to a practical solution for harnessing solar power even after sunset. "This work presents a scalable and environmentally friendly wood-based platform for advanced solar thermal energy harvesting."
by Paul Arnold, Phys.org
edited by Gaby Clark, reviewed by Robert Egan
Source: Engineered wood provides solar power even after the sun goes down
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