AI Article Synopsis
- Photocatalytic conversion of CO to fuel shows promise for solar energy storage and transportation, but creating a low-cost, stable photocatalyst that efficiently utilizes solar energy remains a challenge.
- The study introduces a novel mesoporous p-type/n-type heterojunction material, CuO-TiO, synthesized through annealing Cu/CuO nanocomposites with a TiO precursor, enhancing light absorption and charge separation.
- This innovative photocatalyst achieved a significant methane yield of 221.63 ppm·g·h without using any metal cocatalysts, demonstrating its improved photocatalytic activity.
Article Abstract
Photocatalytic CO conversion to fuel offers an exciting prospect for solar energy storage and transportation thereof. Several photocatalysts have been employed for CO photoreduction; the challenge of realizing a low-cost, readily synthesized photocorrosion-stable photocatalytic material that absorbs and successfully utilizes a broad portion of the solar spectrum energy is as yet unmet. Herein, a mesoporous p-type/n-type heterojunction material, Cu O-TiO ( = 1, 2), is synthesized via annealing of Cu/CuO nanocomposites mixed with a TiO precursor (TiCl). Such an experimental approach in which two materials of diverse bandgaps are coupled provides a simultaneous opportunity for greater light absorption and rapid charge separation because of the intrinsic p-n heterojunction nature of the material. As detailed herein, this heterostructured photocatalyst demonstrates an improved photocatalytic activity. With the CO reduction of our optimal sample (augmented light absorption, efficacious charge separation, and mesoporosity) that utilizes no metal cocatalysts, a remarkable methane yield of 221.63 ppm·g·h is achieved.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6640778 | PMC |
| http://dx.doi.org/10.1021/acsomega.6b00164 | DOI Listing |
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