First-Principles-Based Insight into Electrochemical Reactivity in a Cobalt-Carbonate-Hydrate Pseudocapacitor

TL;DR

This study uses first-principles simulations to analyze the structure and electrochemical stability of cobalt carbonate hydroxide, revealing strong hydrogen bonds that stabilize the crystal and influence its growth and reactivity in pseudocapacitors.

Contribution

It provides a detailed first-principles analysis of hydrogen positions and deprotonation reactions in CCH, clarifying structural stability and growth mechanisms relevant to pseudocapacitor performance.

Findings

Deprotonation does not occur within the crystal due to strong H-bonds.

Computed deprotonation potential exceeds the experimental window.

H-bonds influence 1-D crystal growth along specific planes.

Abstract

Cobalt carbonate hydroxide (CCH) is a pseudocapacitive material with remarkably high capacitance and cycle stability. Previously, it was reported that CCH pseudocapacitive materials are orthorhombic in nature. Recent structural characterization has revealed that they are hexagonal in nature; however, their H positions still remain unclear. In this work, we carried out first-principles simulations to identify the H positions. Through the simulations, we could consider various fundamental deprotonation reactions inside the crystal and computationally evaluate the electromotive forces (EMF) of the deprotonation ($V_\mathrm{dp}$). Compared with the experimental potential window of the reaction ($< 0.6$ V (vs. saturated calomel electrode (SCE))), the computed $V_\mathrm{dp}$ (vs. SCE) value ($3.05$ V) was beyond the potential window, indicating that deprotonation never occurred inside the crystal. This may be attributed to the strongly formed hydrogen-bonds (H-bonds) in the crystal, thereby leading to the structural stabilization. We further investigated the crystal anisotropy in an actual capacitive material by considering the growth mechanism of the CCH crystal. By associating our X-ray diffraction (XRD) peak simulations with experimental structural analysis, we found that the H-bonds formed between CCH $\{(\bar{1}\bar{1}\bar{1}), (2\bar{1}\bar{1}), (2\bar{1}1)\}$ planes (approximately parallel to $ab$-plane) can result in 1-D growth (stacked along with $c$-axis).