2D MXenes polar catalysts for multi-renewable energy harvesting applications

MXene materials are regarded as versatile catalysts for multi-energy utilization, however, designing a single system for multiple energy harvesting applications is challenging. Here, the authors theoretically and experimentally validate the utilization of multiple energy sources by MXene materials. The synchronous harvesting and conversion of multiple renewable energy sources for chemical fuel production and environmental remediation in a single system is a holy grail in sustainable energy technologies. However, it is challenging to develop advanced energy harvesters that satisfy different working mechanisms. Here, we theoretically and experimentally disclose the use of MXene materials as versatile catalysts for multi-energy utilization. Ti3C2TX MXene shows remarkable catalytic performance for organic pollutant decomposition and H-2 production. It outperforms most reported catalysts under the stimulation of light, thermal, and mechanical energy. Moreover, the synergistic effects of piezo-thermal and piezo-photothermal catalysis further improve the performance when using Ti3C2TX. A mechanistic study reveals that hydroxyl and superoxide radicals are produced on the Ti3C2TX under diverse energy stimulation. Furthermore, similar multi-functionality is realized in Ti2CTX, V2CTX, and Nb2CTX MXene materials. This work is anticipated to open a new avenue for multisource renewable energy harvesting using MXene materials.

Automated summary

MXene materials are shown to utilize multiple energy sources for various applications. This study demonstrates the possibility of synchronously harvesting and converting multiple renewable energy sources using MXene materials, which is an important goal in sustainable energy technologies. The researchers also reveal the remarkable catalytic performance of Ti3C2TX MXene for organic pollutant decomposition and H-2 production under different energy stimulations.