2019
DOI: 10.1002/batt.201900031
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Safe Lithium‐Metal Anodes for Li−O2 Batteries: From Fundamental Chemistry to Advanced Characterization and Effective Protection

Abstract: Rechargeable LiÀ O 2 batteries play an increasing important role as energy storage devices, which have both, a high capacity anode and a cathode using an inexhaustible resource. As a key component in LiÀ O 2 batteries, the Li-metal anode suffers from major drawbacks related to Li dendrite formation and SEI layer growth, which are also major issues for Li-metal rechargeable batteries. This review presents an overview on the scientific challenges, fundamental mechanisms and modification strategies of Li-metal an… Show more

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Cited by 73 publications
(62 citation statements)
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References 140 publications
(174 reference statements)
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“…Besides this, being in the air, which includes only a small amount of H 2 O, can give rise to the very fast corrosion of Li metal to form a layer containing Li carbonate (Li 2 CO 3 ), Li nitride (Li 3 N), and Li hydroxide (LiOH). [143][144][145] This corrosion brings about some critical problems, such as low reversibility, the accumulation of byproducts, an increase in overpotential, depletion of the electrolyte, the formation of unstable SEI layers, and eventually leads to the premature death of LiÀ O 2 batteries. Accordingly, besides many studies that have been carried out on the cathode side, such as structural modification, improvements in the catalyst activity, and redox mediator introduction, the development of practical and effective ways to protect Li metal is vital for commercialization of the LiÀ O 2 battery, while still very challenging.…”
Section: Metal Anodes For Lià Oxygen Batteriesmentioning
confidence: 99%
“…Besides this, being in the air, which includes only a small amount of H 2 O, can give rise to the very fast corrosion of Li metal to form a layer containing Li carbonate (Li 2 CO 3 ), Li nitride (Li 3 N), and Li hydroxide (LiOH). [143][144][145] This corrosion brings about some critical problems, such as low reversibility, the accumulation of byproducts, an increase in overpotential, depletion of the electrolyte, the formation of unstable SEI layers, and eventually leads to the premature death of LiÀ O 2 batteries. Accordingly, besides many studies that have been carried out on the cathode side, such as structural modification, improvements in the catalyst activity, and redox mediator introduction, the development of practical and effective ways to protect Li metal is vital for commercialization of the LiÀ O 2 battery, while still very challenging.…”
Section: Metal Anodes For Lià Oxygen Batteriesmentioning
confidence: 99%
“…The molecular orbitals at different nuclear geometries were optimized using a 2-state-averaged CASSCF (1 singlet + 1 triplet) with the ma-def2-TZVP basis set [31] within a [18,12] active space. CASSCF wavefunctions were optimized using an equal weight for the singlet and triplet state.…”
Section: Experimental Partmentioning
confidence: 99%
“…In all computations, the resolution of identity (RI) approximation for the evaluation of two-electron integrals was employed, which allows remarkable time savings at the price of a negligible loss of accuracy. The [18,12] active space was chosen to include all the p-type valence orbitals and electrons from the oxygens (12 orbitals, 18 electrons). The valence orbitals of the cations (1 s of H and 2 s of Li), when included in the active space in a test calculation, turned out to be substantially inactive, with occupation numbers very close to zero; therefore, we excluded them in the final calculations, leading to a 18-in-12 active space.…”
Section: Experimental Partmentioning
confidence: 99%
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