▎ 摘　　要

The development of direct methanol fuel cell (DMFC) technology is an effective way to solve the problems of environmental pollution and energy shortage, while the scarcity of the highly-efficient anode catalysts with low cost severely limits its commercial use. In this work, we report a robust and convenient approach for the bottom-up construction of well-dispersive Pt nanocrystals anchored onto three-dimensional (3D) porous boron and nitrogen double-doped reduced graphene oxide-carbon nanotube frameworks (Pt/BNRGO-CNT) via a controllable co-assembly process. This architectural design can achieve a series of useful structural merits, such as 3D cross-linked porous network, large presence of B and N atoms, homogeneous Pt dispersibility, and high electrical conductivity. Consequently, the resulting Pt/BNRGO-CNT electrocatalysts exhibit excellent cat-alytic activity, strong anti-toxicity ability, and good long-term stability for methanol oxidation reaction, far exceeding those of Pt catalysts supported by the conventional undoped reduced graphene oxide, carbon nan-otube, and carbon black matrixes.