Relocating Conjugated 2P Valence Electrons in Carbon Host to Stabilize I<sup>+</sup> for Novel Zn‐I<sub>2</sub> Battery
Pengfang Zhang, Meng‐Meng Ma, Xu Wu, Wen‐Wen Chu, Shuling Xu, H. Su, Fanghui Du, Lingyang Liu, Xiao-Jun Kong, Hengxiang Li, Lei Ding, Zhaoyang Wang, Zong‐Ge Li, Yao Zhou, Shaojian Zhang, Yao Wang, Chun‐Hua Zhen, Jun‐Tao Li
Abstract
Abstract Zn‐I 2 battery with four‐electron reaction path (I − /I 2 /I + ) in the cathode delivers high energy density, which however is thermodynamically not favored as I + is metastable. Herein, it is demonstrated that conjugated 2P valence electrons in graphitic framework can be relocated, offering chances to stabilize I + species. Combinations of 2P elements (B, N, C, O) with various configurations are first screened computationally, identifying O─B─C─N as the optimal structure. In this B‐centered domain, the adjacent O and meta‐positioned N, owing to more valence electrons and higher electronegativity, are found to withdraw electrons from surrounding C atoms and enrich 2P z orbital of the electron‐deficient B site at Fermi level; with weak electronegativity, the electronically enriched B tends to donate electrons to the reactants, which thus can stabilize I + and also enhance adsorption of iodine species on the carbon host. Carbon nanosheets with abundant O─B─C─N domains are developed accordingly; the relevant Zn‐I 2 battery shows a large capacity of 420.3 mAh g −1 and high coulombic efficiency of 98.9% under 0.8 A g −1 ; moreover, it can stand for 9000 cycles with a capacity retention of 88.8%. This computation‐guided study presents how the interplay of various 2p‐elements can be manipulated to pursue an efficient carbon host for novel Zn‐I 2 batteries.