A dual heterostructure enables the stabilization of 1T-rich MoSe2 for enhanced storage of sodium ions
journal contribution
posted on 2024-11-17, 15:00authored byYunfeng Chao, Shenghui Jia, Jinzhao Li, Guohui Chen, Lu Liu, Fei Tang, Jianhua Zhu, Caiyun Wang, Xinwei Cui
Electron injection effectively induces the formation of a 1T-rich phase to address the low conductivity of MoSe2. Nevertheless, overcoming the inherent metastability of the 1T phase (particularly during the conversion reactions that entail the decomposition-reconstruction of MoSe2 and volume expansion) remains a challenge. Guided by DFT results, we designed a composite with bimetal selenides-based heterostructures anchored on reduced graphene oxide (rGO) nanosheets (G-Cu2Se@MoSe2) to obtain stabilized 1T-rich MoSe2 and enhanced ion transfer. The construction of 1T-rich MoSe2 and built-in electric fields (BiEF) through electron transfer at the heterointerfaces were realized. Moreover, the rGO-metal selenides heterostructures with in situ-formed interfacial bonds could facilitate the reconstruction of the 1T-rich MoSe2-involved heterostructure and interfacial BiEF. Such a dual heterostructure endowed G-Cu2Se@MoSe2 with an excellent rate capability with a capacity of 288 mA h g−1 at 50 A g−1 and superior cycling stability with a capacity retention ratio of 89.6% (291 mA h g−1) after 15 000 cycles at 10 A g−1. Insights into the functional mechanism and structural evolution of the 1T MoSe2-involved dual heterostructure from this work may provide guidelines for the development of MoSe2 and phase-engineering strategies for other polymorphistic materials.
Funding
National Natural Science Foundation of China (52202119)