Anionic Activity in Fast-Charging Batteries: Recent Advances, Prospects, and Challenges

Xu, Shumao; Peng, Baixin; Pang, Xin; Huang, Fuqiang

doi:10.1021/acsmaterialslett.2c00810

Cited by 12 publications

(7 citation statements)

References 186 publications

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“…[41][42][43] As for the theoretical correction, the Mott-Hubbard effect illustrates the band splitting of (M-O)* into the filled lower Hubbard band (LHB) and empty upper Hubbard band respectively by considering the strong on-site d-d Coulomb and exchange interaction U (Figure 1b). [21,44,45] The bandgap between the M-O and (M-O)* bands is called the charge-transfer energy (Δ), which is dependent on the electronegativity between M and O, and the Madelung potential. [46,47] Note that U is inversely related to the orbital volume and valence state of the d-metal species, and the disparity between U and Δ may create the difference in the contribution of 3d electrons close to E F , which displays the potential in modulating M-O covalency.…”

Section: Theoretical Hypothesismentioning

confidence: 99%

Reinforcing CoO Covalency via Ce(4f)─O(2p)─Co(3d) Gradient Orbital Coupling for High‐Efficiency Oxygen Evolution

et al. 2023

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Rare-earth (RE)-based transition metal oxides (TMO) are emerging as a frontier toward the oxygen evolution reaction (OER), yet the knowledge regarding their electrocatalytic mechanism and active sites is very limited. In this work, atomically dispersed Ce on CoO is successfully designed and synthesized by an effective plasma (P)-assisted strategy as a model (P-Ce SAs@CoO) to investigate the origin of OER performance in RE-TMO systems. The P-Ce SAs@CoO exhibits favorable performance with an overpotential of only 261 mV at 10 mA cm −2 and robust electrochemical stability, superior to individual CoO. X-ray absorption spectroscopy and in situ electrochemical Raman spectroscopy reveal that the Ce-induced electron redistribution inhibits Co-O bond breakage in the Co-O-Ce unit site. Theoretical analysis demonstrates that the gradient orbital coupling reinforces the Co-O covalency of the Ce(4f )─O(2p)─Co(3d) unit active site with an optimized Co-3d-e g occupancy, which can balance the adsorption strength of intermediates and in turn reach the apex of the theoretical OER maximum, in excellent agreement with experimental observations. It is believed that the establishment of this Ce-CoO model can set a basis for the mechanistic understanding and structural design of high-performance RE-TMO catalysts.

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Section: Theoretical Hypothesismentioning

confidence: 99%

Reinforcing CoO Covalency via Ce(4f)─O(2p)─Co(3d) Gradient Orbital Coupling for High‐Efficiency Oxygen Evolution

et al. 2023

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“…Given substantial progress in frameworktype SIB cathodes with outstanding rate performance, [4,5] simultaneous research on high-rate matching anodes is essential to enabling the widespread application of high-performance SIBs. [6][7][8][9][10][11][12][13][14] Bismuth (Bi) has attracted considerable attention among various candidates of anode materials owing to its high volumetric capacity (3750 mAh cm −3 ) and moderate reaction potential (0.6 V vs. Na + /Na). [15][16][17] In addition, Bi has a narrow bandgap and high ionic conductivity that benefits Na + diffusion.…”

Section: Introductionmentioning

confidence: 99%

“…From the molecular point of view, the activity of chemical reactions originates from the weak bonding interactions and possible migratory behavior of atoms. [35][36][37] Comparatively, the intercalation-type electrode materials with strong metal-anion bonding undergo a bonding strength decrease rather than bond breakage during ion insertion, [6,38] which resists deformation under stress and maintains a stable framework when incorporated with active components. [39][40][41] Moreover, 2D intercalation host frameworks with high electrical conductivity have been proven to not only buffer volume expansion of alloying metal but also greatly improve rate performance.…”

Section: Introductionmentioning

confidence: 99%

Quasi‐Topological Intercalation Mechanism of Bi_0.67NbS₂ Enabling 100 C Fast‐Charging for Sodium‐Ion Batteries

et al. 2023

Advanced Energy Materials

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Alloying-type bismuth with high volumetric capacity has emerged as a promising anode for sodium-ion batteries but suffers from large volume expansion and continuous pulverization. Herein, a coordination constraint strategy is proposed, that is, chemically confining atomic Bi in an intercalation host framework via reconstruction-favorable linear coordination bonds, enabling a novel quasi-topological intercalation mechanism. Specifically, micron-sized Bi 0.67 NbS 2 is synthesized, in which the Bi atom is linearly coordinated with two S atoms in the interlayer of NbS 2 . The robust Nb−S host framework provides fast ion/electron diffusion channels and buffers the volume expansion of Na + insertion, endowing Bi 0.67 NbS 2 with a lower energy barrier (0.141 vs. 0.504 eV of Bi). In situ and ex situ characterizations reveal that Bi atom alloys with Na + via a solid-solution process and is constrained by the reconstructed Bi−S bonds after dealloying, realizing complete recovery of crystalline Bi 0.67 NbS 2 phase to avoid the migration and aggregation of atomic Bi. Accordingly, the Bi 0.67 NbS 2 anode delivers a reversible capacity of 325 mAh g −1 at 1 C and an extraordinary ultrahigh-rate stability of 226 mAh g −1 at 100 C over 25 000 cycles. The proposed quasi-topological intercalation mechanism induced by coordinated mode modulation is expected to be be conducive to the practical electrode design for fast-charging batteries.

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“…Given substantial developments in high‐performance SIB cathodes with kinetically favorable Na + storage channels, [ 7–9 ] the simultaneous exploration of advanced anodes to confer high capacities and rate capabilities is crucial to enabling the widespread application of SIBs. [ 10–17 ] Among various anode candidates, bismuth sulfide (Bi 2 S 3 ) with a unique layered structure has attracted considerable attention due to the high theoretical gravimetric capacity (625 mAh g −1 ), high volumetric capacity (4250 mAh cm −3 ), and low cost. [ 18–21 ] Nevertheless, the advantages are overshadowed by the inferior cycling and rate performance due to the continuous aggregation and pulverization of Bi caused by the large volume expansion (≈244%) during sodiation process.…”

Section: Introductionmentioning

confidence: 99%

Intercalative Motifs‐Induced Space Confinement and Bonding Covalency Enhancement Enable Ultrafast and Large Sodium Storage

Peng

et al. 2023

Adv Funct Materials

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Alloying-type metal sulfides with high theoretical capacities are promising anodes for sodium-ion batteries, but suffer from sluggish sodiation kinetics and huge volume expansion. Introducing intercalative motifs into alloyingtype metal sulfides is an efficient strategy to solve the above issues. Herein, robust intercalative InS motifs are grafted to high-capacity layered Bi 2 S 3 to form a cation-disordered (BiIn) 2 S 3 , synergistically realizing high-rate and large-capacity sodium storage. The InS motif with strong bonding serves as a space-confinement unit to buffer the volume expansion, maintaining superior structural stability. Moreover, the grafted high-metallicity Indium increases the bonding covalency of BiS, realizing controllable reconstruction of BiS bond during cycling to effectively prevent the migration and aggregation of atomic Bi. The novel (BiIn) 2 S 3 anode delivers a high capacity of 537 mAh g −1 at 0.4 C and a superior high-rate stability of 247 mAh g −1 at 40 C over 10000 cycles. Further in situ and ex situ characterizations reveal the in-depth reaction mechanism and the breakage and formation of reversible BiS bonds. The proposed space confinement and bonding covalency enhancement strategy via grafting intercalative motifs can be conducive to developing novel high-rate and large-capacity anodes.

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Anionic Activity in Fast-Charging Batteries: Recent Advances, Prospects, and Challenges

Cited by 12 publications

References 186 publications

Reinforcing CoO Covalency via Ce(4f)─O(2p)─Co(3d) Gradient Orbital Coupling for High‐Efficiency Oxygen Evolution

Reinforcing CoO Covalency via Ce(4f)─O(2p)─Co(3d) Gradient Orbital Coupling for High‐Efficiency Oxygen Evolution

Quasi‐Topological Intercalation Mechanism of Bi_0.67NbS₂ Enabling 100 C Fast‐Charging for Sodium‐Ion Batteries

Intercalative Motifs‐Induced Space Confinement and Bonding Covalency Enhancement Enable Ultrafast and Large Sodium Storage

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Anionic Activity in Fast-Charging Batteries: Recent Advances, Prospects, and Challenges

Cited by 12 publications

References 186 publications

Reinforcing CoO Covalency via Ce(4f)─O(2p)─Co(3d) Gradient Orbital Coupling for High‐Efficiency Oxygen Evolution

Reinforcing CoO Covalency via Ce(4f)─O(2p)─Co(3d) Gradient Orbital Coupling for High‐Efficiency Oxygen Evolution

Quasi‐Topological Intercalation Mechanism of Bi0.67NbS2 Enabling 100 C Fast‐Charging for Sodium‐Ion Batteries

Intercalative Motifs‐Induced Space Confinement and Bonding Covalency Enhancement Enable Ultrafast and Large Sodium Storage

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Quasi‐Topological Intercalation Mechanism of Bi_0.67NbS₂ Enabling 100 C Fast‐Charging for Sodium‐Ion Batteries