Research progress on electrolytes for fast-charging lithium-ion batteries

“…[4] The research and development of lithiumion batteries (LIBs) have been instrumental in reducing costs and increasing safety, particularly by addressing the issue of dendrite formation on electrodes and consequent short circuiting. [5,6] However, the use of LIBs is not without its drawbacks, such as the limited energy density and capacity of electrodes, the risk of thermal runaway of organic electrolytes, and the scarcity of lithium resources. [7][8][9] Moreover, the use of 1 kWh of LIB results in the emission of approximately 75 kg of CO 2 , which is equivalent to the combustion of 35 L of gasoline.…”

Improved Strategies for Separators in Zinc‐Ion Batteries

“…[4] The research and development of lithiumion batteries (LIBs) have been instrumental in reducing costs and increasing safety, particularly by addressing the issue of dendrite formation on electrodes and consequent short circuiting. [5,6] However, the use of LIBs is not without its drawbacks, such as the limited energy density and capacity of electrodes, the risk of thermal runaway of organic electrolytes, and the scarcity of lithium resources. [7][8][9] Moreover, the use of 1 kWh of LIB results in the emission of approximately 75 kg of CO 2 , which is equivalent to the combustion of 35 L of gasoline.…”

Improved Strategies for Separators in Zinc‐Ion Batteries

“…3 Out of all the ESD contenders, lithium-ion batteries are a popular choice among ESD candidates due to their high energy density and long-term cycling stability. 4,5 However, the thorny issues of their expensive price tag, scarcity of lithium, and inadequate safety have prompted the exploration of reliable alternatives. 6 Zinc ion batteries (ZIBs) are among the most promising ESD technologies of the future, given their advantageous kinetics, high theoretical capacity (820 mA h g −1 ), and relatively low electrochemical potential (−0.76 V vs. the standard hydrogen electrodes) of zinc metal anodes, as well as economic and environmental benefits (Fig.…”

Improved strategies for ammonium vanadate-based zinc ion batteries

“…[5][6][7] Lithium-ion batteries (LIBs) are at the forefront of rechargeable battery applications, playing an important role in the energy eld of modern society due to their extremely high current density, operating voltage, good rechargeability, and mature commercialization. [8][9][10][11][12] In addition to the dwindling natural lithium resources on Earth, the available lithium resources are also restricted because they are mainly extracted from underground resources such as Li 2 CO 3 and LiOH ores. 13 Furthermore, the inherent safety and environmental concerns of LIBs derived from volatile and toxic organic electrolytes hinder their advancement.…”

Research progress on modified Zn substrates in stabilizing zinc anodes