Tailoring Local Electrolyte Solvation Structure via a Mesoporous Molecular Sieve for Dendrite‐Free Zinc Batteries

Miao, Zhenyu; Zhang, Feng; Zhao, Hang; Du, Min; Li, Houzhen; Jiang, Hechun; Li, Wenzhi; Sang, Yuanhua; Liu, Hong; Wang, Shuhua

doi:10.1002/adfm.202111635

Cited by 76 publications

(50 citation statements)

References 56 publications

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“…To quantify the electrode reactivity, the activation energy ( E a ) of Zn 2+ diffusion was measured according to R ct in the temperature range of 25–85°C (Figure S11). E a was calculated by the Arrhenius Equation (3): 40

\frac{1}{R_{ct}} = A \exp (- \frac{E_{a}}{italicRT})

where A is the frequency factor, R is the gas constant and T is the temperature. Figure S11 shows a higher E a for (Zn,en)VO (15.13 kJ mol −1 ) than for N‐(Zn,en)VO (8.73 kJ·mol −1 ), revealing that the nitridation treatment effectively improved the electrochemical activity of the cathodic material.…”

Section: Resultsmentioning

confidence: 99%

Oxygen vacancies and N‐doping in organic–inorganic pre‐intercalated vanadium oxide for high‐performance aqueous zinc‐ion batteries

Zhang

Miao

et al. 2022

InfoMat

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Pre‐intercalation of metal ions into vanadium oxide is an effective strategy for optimizing the performance of rechargeable zinc‐ion battery (ZIB) cathodes. However, the battery long‐lifespan achievement and high‐capacity retention remain a challenge. Increasing the electronic conductivity while simultaneously prompting the cathode diffusion kinetics can improve ZIB electrochemical performance. Herein, N‐doped vanadium oxide (N‐(Zn,en)VO) via defect engineering is reported as cathode for aqueous ZIBs. Positron annihilation and electron paramagnetic resonance clearly indicate oxygen vacancies in the material. Density functional theory (DFT) calculations show that N‐doping and oxygen vacancies concurrently increase the electronic conductivity and accelerate the diffusion kinetics of zinc ions. Moreover, the presence of oxygen vacancies substantially increases the storage sites of zinc ions. Therefore, N‐(Zn,en)VO exhibits excellent electrochemical performance, including a peak capacity of 420.5 mA h g−1 at 0.05 A g−1, a high power density of more than 10 000 W kg−1 at 65.3 Wh kg−1, and a long cycle life at 5 A g−1 (4500 cycles without capacity decay). The methodology adopted in our study can be applied to other cathodic materials to improve their performance and extend their practical applications.

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\frac{1}{R_{ct}} = A \exp (- \frac{E_{a}}{italicRT})

Section: Resultsmentioning

confidence: 99%

Oxygen vacancies and N‐doping in organic–inorganic pre‐intercalated vanadium oxide for high‐performance aqueous zinc‐ion batteries

Zhang

Miao

et al. 2022

InfoMat

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“…For example, molecular sieves of Mobil composition of matter number 41 (MCM41) with ordered mesoporous channels are constructed to tailor the local electrolyte solvation structure on the zinc surface. [48] In this work, MCM41 is physically coupled with a Zn anode, which provides Reproduced with permission. [45] Copyright 2020, Wiley-VCH.…”

Section: Metal Framework Modified Electrolytementioning

confidence: 99%

Solvation Structures in Aqueous Metal‐Ion Batteries

Wang

et al. 2022

Advanced Energy Materials

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Aqueous batteries have attracted great attention due to their inherent low cost, intrinsic safety, and environmental friendliness. Because of intrinsic oxygen evolution reactions (OER) and hydrogen evolution reactions (HER) via water splitting, aqueous batteries possess narrow electrochemical stability windows (ESWs, theoretical ESW is 1.23 V), leading to low output voltage and low delivered capacity, and thus low energy density. Meanwhile, the parasitic side reactions of electrode materials dissolution, gas evolution, and dendrite growth can shorten cyclic stability of aqueous batteries. The above deep‐seated challenges are closely related to the solvation structure of metal ions, which can be settled by adjusting and regulating the solvation structure. This review summarizes the research progress in solvation structures in metal‐ion batteries. First, the design principles of the solvation structure and its impact on battery performance are introduced. Second, the regulation of the solvation structure and the research progress are introduced from three points of view: high concentration salt strategies, MOF modification and electrolyte additives. After that, the commonly used characterization methods for solvation structure are summarized. Finally, the existing problems and challenges in the frontier research of solvation structure research are summarized.

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“…Numerous attempts at regulating the Li + solvation structure in electrolytes have been explored, such as solvents with low dipole moments, , electrolyte additives, − and high concentration or local high concentration electrolytes (HCEs or LHCEs). − However, compared with the exploration of electrolytes, the firsthand and significant impacts of separators serving as reservoirs for electrolytes on the Li + solvation structure have been severely neglected. − In addition to homogenizing the Li + flux − and improving the transference number of Li + ( t Li + ), ,, the Li + solvation sheath can also be altered by chemical bonds or nanochannels introduced by the special separator modification. , Actually, in addition to the nanochannels produced by the special treatment, the solvation structure in the electrolyte confined in nanochannels of porous inorganic particles is also disparate from the normal state. − Hence, introducing porous inorganic particles into the separator coating to regulate the solvation structure is a topic worth discussing.…”

Section: Introductionmentioning

confidence: 99%

Regulating Solvation Structures Enabled by the Mesoporous Material MCM-41 for Rechargeable Lithium Metal Batteries

Zhao

Wang

et al. 2022

ACS Nano

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For developing the reversible lithium metal anode, constructing an ideal solid electrolyte interphase (SEI) by regulating the Li + solvation structure is a powerful way to overcome the major obstacles of lithium dendrite and limited Coulombic efficiency (CE). Herein, spherical mesoporous molecular sieve MCM-41 nanoparticles are coated on a commercial PP separator and used to regulate the Li + solvation structure for lithium metal batteries (LMBs). The regulated solvation structure exhibits an agminated state with more contact ion pairs (CIPs) and ionic aggregates (AGGs), which successfully construct a homogeneous inorganic-rich SEI in the lithium anode. Meanwhile, the regulated solvation structure weakens the interaction between the solvents and Li + , resulting in low Li + desolvation energy and uniform Li deposition. Thus, a high CE (∼96.76%), dendrite-free Li anode, and stable Li plating/stripping cycling for approximately 1000 h are achieved in the regulated carbonate-based electrolyte without any additives. Therefore, regulating the Li + solvation structure in the electrolyte by employing a mesoporous material is a forceful way to construct an ideal SEI and harness lithium metal.

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Tailoring Local Electrolyte Solvation Structure via a Mesoporous Molecular Sieve for Dendrite‐Free Zinc Batteries

Cited by 76 publications

References 56 publications

Oxygen vacancies and N‐doping in organic–inorganic pre‐intercalated vanadium oxide for high‐performance aqueous zinc‐ion batteries

Oxygen vacancies and N‐doping in organic–inorganic pre‐intercalated vanadium oxide for high‐performance aqueous zinc‐ion batteries

Solvation Structures in Aqueous Metal‐Ion Batteries

Regulating Solvation Structures Enabled by the Mesoporous Material MCM-41 for Rechargeable Lithium Metal Batteries

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