Carbon‐Hybridized Hydroxides for Energy Conversion and Storage: Interface Chemistry and Manufacturing

Abstract: Carbon‐hybridized hydroxides (CHHs) have been intensively investigated for uses in the energy conversion/storage fields. Nevertheless, the intrinsic structure–activity relationships between carbon and hydroxides within CHHs are still blurry, which hinders the fine modulation of CHHs in terms of practical applications to some degree. This review aims to figure out the intrinsic role of carbon materials in CHHs with a focus on the interface chemistry and the engineering strategy in‐between two components. The fu… Show more

“…Hence, developing inexpensive, stable, and highly efficient catalysts for the OER is still extre-mely needed. Based on this, non-noble metals such as carbides, 9,10 phosphides, 11,12 nitrides, 13,14 oxides, 15,16 hydroxides, 17,18 and sulfides 19,20 have been extensively studied and applied in the OER.…”

Application of changing the valence state of metals through the reaction time for efficient oxygen evolution reaction

“…Hence, developing inexpensive, stable, and highly efficient catalysts for the OER is still extre-mely needed. Based on this, non-noble metals such as carbides, 9,10 phosphides, 11,12 nitrides, 13,14 oxides, 15,16 hydroxides, 17,18 and sulfides 19,20 have been extensively studied and applied in the OER.…”

Application of changing the valence state of metals through the reaction time for efficient oxygen evolution reaction

“…However, there are still many issues that need to be focused on such as whether the pore structure plays a crucial role in ion storage and, if so, which type of pore can affect the mass transfer of electrolyte ions in an electrochemical environment. 15 As such, in-depth insights into structure-driven charge/electrolyte transport at the micro-scale are still required for achieving "dual-high" (high energy/power density) devices.…”

Toward record high Zn²⁺ storage in carbon electrodes via pore confinement engineering

“…The escalating demand for renewable energy stimulates the growing pursuit of highly stable, eco-friendly, and economically viable energy storage technologies. [1][2][3][4][5][6] Aqueous zinc batteries (AZBs) are regarded as some of the most promising candidates for energy storage due to the multiple advantages of high theoretical capacity (820 mA h g À1 ), appropriate electrochemical potential (À0.76 V vs. the standard hydrogen electrode) and low cost of Zn anodes. [7][8][9][10] Moreover, non-ammable aqueous electrolytes simplify the manufacturing requirements and ensure high safety of AZBs during operation.…”

Rational design of a dual-gradient zincophilic–conductive interphase for dendrite-free zinc batteries