High-performance and cost effective electrocatalysts used for oxygen evolution reactions (OER) are indispensable in renewable-energy technologies. As an important 3D class of porous materials, Metal organic frameworks (MOF) with designable topological structures and compositions have been used as templates to obtain diverse functional materials. In this paper, ZnCo2O4@ C-MWCNTs has been successfully synthesized by embedding dual-MOF into MWCNTs followed by calcinations under N-2 and air atmosphere in turn. The ZnCo2O4@ C-MWCNTs hybrid exhibits enhanced OER performance in terms of an onset potential (1.45 V vs. RHE) and a low overpotential (327 mV) at 10 mA cm(-2). It is noteworthy that the potentials of ZnCo2O4@ C-MWCNTs remain almost constant for 25 h in alkaline solution. Compared with many MOF derived matrix for OER applications, in-situ carbon formed during calcination process under N-2 atmosphere can not only improve the material's conductivity, but also prevent the agglomeration of active nanoparticles. The design concept of dual-MOFs-doped MWCNTs can be significantly expanded to fabricate other novel and stable catalysts for a wide range of applications. (C) 2017 Elsevier Ltd. All rights reserved.