<p>The electrochemical upgrading of methanol to formate is constrained by CO poisoning from *CHO intermediate dehydrogenation, hindering its industrial application. Herein, we report that engineering atomically polarized Pt<sup>δ+</sup>-Pt<sup>δ–</sup> dipoles on Ti felt achieves a formate Faradaic efficiency of 99% at +0.9 V <i>vs</i>. RHE, which is better than that of commercial Pt/C (62%). Moreover, a formate production rate of 945 mmol g<sub>Pt</sub><sup>–1</sup> h<sup>–1</sup> is achieved with stable performance for more than 5 days at 100 mA cm<sup>–2</sup>. These dipoles comprise spatially adjacent electron-deficient Pt<sup>δ+</sup> bonded to lattice O and electron-rich Pt<sup>δ–</sup> coordinated to unsaturated Ti atoms working synergistically. The Pt<sup>δ+</sup> site dehydrogenates CH<sub>3</sub>OH to *CHO, which adsorbs across the dipole in a side-on Pt<sup>δ+</sup>–OHC–Pt<sup>δ–</sup> bridging configuration. Within this configuration, Pt<sup>δ–</sup> donates electrons via <i>d</i>→<i>π</i>* backdonation to the <i>π</i>* antibonding orbital of *CHO, steering its direct hydroxylation and generating electrostatic repulsion for rapid HCOOH desorption. This strategy reduces environmental impact by 88% and carbon emissions by 11% relative to conventional thermal routes, demonstrating the potential of dipole engineering for C<sub>1</sub> electrochemistry.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Selective electrochemical methanol to formate conversion via direct CHO hydroxylation on Ptδ+-Ptδ– dipoles

  • Ke Cheng,
  • Hao Li,
  • Bing Zhou,
  • Haopeng Pei,
  • Lufa Hu,
  • Long Zhao,
  • Xingyue Zou,
  • Jiaxian Wang,
  • Qian Zheng,
  • Rui Zhao,
  • Yan Zhang,
  • Anping Liu,
  • Zewen Wu,
  • Guangming Zhan,
  • Mingming Guo,
  • Lizhi Zhang

摘要

The electrochemical upgrading of methanol to formate is constrained by CO poisoning from *CHO intermediate dehydrogenation, hindering its industrial application. Herein, we report that engineering atomically polarized Ptδ+-Ptδ– dipoles on Ti felt achieves a formate Faradaic efficiency of 99% at +0.9 V vs. RHE, which is better than that of commercial Pt/C (62%). Moreover, a formate production rate of 945 mmol gPt–1 h–1 is achieved with stable performance for more than 5 days at 100 mA cm–2. These dipoles comprise spatially adjacent electron-deficient Ptδ+ bonded to lattice O and electron-rich Ptδ– coordinated to unsaturated Ti atoms working synergistically. The Ptδ+ site dehydrogenates CH3OH to *CHO, which adsorbs across the dipole in a side-on Ptδ+–OHC–Ptδ– bridging configuration. Within this configuration, Ptδ– donates electrons via dπ* backdonation to the π* antibonding orbital of *CHO, steering its direct hydroxylation and generating electrostatic repulsion for rapid HCOOH desorption. This strategy reduces environmental impact by 88% and carbon emissions by 11% relative to conventional thermal routes, demonstrating the potential of dipole engineering for C1 electrochemistry.