Sono‐Piezo‐Photosynthesis of Ethylene and Acetylene from Bioethanol under Ambient Conditions

• Published in: Advanced functional materials Vol. 35; no. 27
• Main Authors: Jiang, Yue, Zhang, Jiajun, Ma, Hongyang, Zhou, Shujie, Lin, Hsun‐Yen, Mofarah, Sajjad S., Lockrey, Mark, Lu, Teng, Ren, Hangjuan, Zheng, Xiaoran, Gunawan, Maichael, Huang, Suchen, Huang, Yu‐Chun, Zhuo, Fenglin, Ji, Dali, Hart, Judy N., Liu, Yun, Wu, Jyh Ming, Ashokkumar, Muthupandian, Wang, Danyang, Koshy, Pramod, Sorrell, Charles C.
• Format: Journal Article
• Language: English
• Published: Hoboken Wiley Subscription Services, Inc 01.07.2025
• Subjects: Acetylene; ambient‐condition catalysis; bioethanol conversion; Biofuels; Bismuth titanate; C2 hydrocarbons (ethylene, acetylene); Catalytic converters; Ethylene; ferroelectric/graphene oxide hybrid materials; Graphene; Heterostructures; High temperature; Organic compounds; Photocatalysis; Photosynthesis; Pressure; Room temperature; sono‐piezo‐photocatalysis
• ISSN: 1616-301X; 1616-3028
• DOI: 10.1002/adfm.202425784

The catalytic conversion of bioethanol to ethylene (C2H4) and acetylene (C2H2) offers a transformative approach to sustainable production of two industrial cornerstones for organic compound and polymer syntheses, thereby offering significant economic and environmental advantages. In contrast, current methods for the synthesis of these C2 hydrocarbons rely on energy‐ and carbon‐intensive processes that require high temperatures and pressures. The present work addresses these limitations with a novel, low‐energy, bioethanol‐conversion strategy operating at room temperature and ambient pressure using sono‐piezo‐photocatalysts. A novel heterostructure of graphene oxide fragments (GO) and sodium bismuth titanate (NBT) within a core‐shell microstructure achieved outstanding C2H4 and C2H2 production rates of 134.1 and 55.5 µmol/g/h, respectively. The conversion mechanism is driven by (1) bubble collapse during ultrasound irradiation, generating localized high temperatures (≈4000 K) and pressures (≈100 MPa), and (2) piezo‐photocatalytic tuning of GO/NBT by enhanced charge separation and transfer. DFT simulations revealed detailed sono‐piezo‐photocatalytic conversion pathways, showing significant reductions in energy barriers for C2H4 (22.0 kcal mol−1) and C2H2 (48.0 kcal mol−1) formation. These findings emphasize the critical role of the catalyst in cleaving both C─H and C─O bonds effectively, leading to the desired product formation. A novel sono‐piezo‐photocatalytic strategy enables the conversion of bioethanol to ethylene (C2H4) and acetylene (C2H2) under ambient conditions, addressing the limitations of conventional methods that are high‐temperature and energy‐intensive. By using an advanced graphene oxide/sodium bismuth titanate heterostructure catalyst, this work achieved outstanding production rates of C2 hydrocarbons under the irradiation of ultrasound and light. This work highlights the critical role of the catalyst in improving overall catalytic efficiency by enhancing charge separation, reducing energy barriers, and delivering optimized catalytic pathways.