Superior anchoring effect of a Cu-benzenehexathial MOF as an aluminium–sulfur battery cathode host

Bhauriyal, Preeti; Pathak, Biswarup

doi:10.1039/d0ma00546k

Cited by 22 publications

(31 citation statements)

References 81 publications

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“…, the E b values of S 8 *, Al 2 S 18 *, Al 2 S 12 *, Al 2 S 6 *, and Al 2 S 3 * were −1.81, −2.18, −1.22, −4.18, and −2.97 eV, respectively, in the range of −1.81 to −4.18 eV. A previous study demonstrated that the E b values of S 8 and Al 2 S n species on Cu-BHT MOF were in the range of −1.11 to −3.56 eV and −0.76 to −0.87 eV for the graphene structure 23. This indicated that Ag@Ti 3 C 2 O 2, as a sulfur host, had the ability to adsorb S 8 and Al 2 S n species.…”

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confidence: 88%

“…16−22 Inspired by this, Bhauriyal et al studied the binding strength between Al 2 S n and Cu-benzeneheaxthial (Cu-BHT) MOF by using DFT calculations, suggesting that Cu-BHT MOF could be used as a promising sulfur host for Al−S batteries. 23 However, the interaction mechanism and Al 2 S n conversion remain unclear. First, the main evaluation of sulfur hosts is the binding strength (adsorption energy), and it is generally believed that the stronger the binding is, the better.…”

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confidence: 99%

“…A number of studies have been carried out to provide microscopic insights into the interaction features between sulfur hosts and Li 2 S n and the design of cathode materials based on density functional theory (DFT), showing the effectiveness of theoretical simulations in selecting suitable sulfur hosts and estimating the chemical energy barrier of sulfur reduction. − Inspired by this, Bhauriyal et al studied the binding strength between Al 2 S n and Cu-benzeneheaxthial (Cu-BHT) MOF by using DFT calculations, suggesting that Cu-BHT MOF could be used as a promising sulfur host for Al–S batteries . However, the interaction mechanism and Al 2 S n conversion remain unclear.…”

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confidence: 99%

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Unraveling the Anchoring Effect of MXene-Supported Single Atoms as Cathodes for Aluminum–Sulfur Batteries

Wang

Zheng

Chen

et al. 2022

ACS Materials Lett.

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As an alternative energy storage system, the stable cycle and high-rate performance of aluminum–sulfur (Al–S) batteries are increasingly affected by the dissolution of intermediate Al polysulfide (Al2S n ) into the electrolyte. Introducing anchoring materials that can promote Al2S n conversion is an effective way to solve this problem. However, the lack of an interaction mechanism between Al2S n and anchoring materials hinders the design of anchoring materials. Here, we used single-atom-loaded MXene (SA@MXene) as a representative anchoring material to systematically investigate the binding strength between SA@MXene and Al2S n , the sulfur reduction process on MXene, and their geometric configurations, stabilities, and electronic structures. We evaluated the reaction activity of the various SA@MXene nanosheets and discovered four high-performance cathode candidates for Al–S batteries (SA = Y, Nb, Mo, Tc) with a minimum reaction energy barrier of 0.23 eV. Importantly, to unravel the interaction mechanism between Al2S n and the anchoring material, we proposed an activity volcano by consolidating the decisive S8*, Al2S8*, and Al2S12* binding strengths, which provides a significant roadmap for designing cathodes for Al–S batteries. The proposed study of the Al–S conversion process will benefit the understanding of sulfur chemistry and provide valuable inspiration for the design of other catalytic reaction processes.

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confidence: 99%

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confidence: 99%

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Unraveling the Anchoring Effect of MXene-Supported Single Atoms as Cathodes for Aluminum–Sulfur Batteries

Wang

Zheng

Chen

et al. 2022

ACS Materials Lett.

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“…[ 225 ] Due to price fluctuations and constraints in the supply of cobalt, the momentum of using electric vehicles and grid‐storage applications has come to a standstill which has prompted the researchers to seek alternative cost‐efficient metals. [ 226,227 ] As a result, Bhauriyal et al [ 228 ] employed “a 2D Cu‐benzenehexathial (Cu‐BHT) MOF (Figure 11f)” as a potential anchoring host for S‐cathode in Al/S battery. The conductive nature of Cu‐BHT‐MOF could successfully compensate for the intrinsic insulating nature of sulfur‐based products.…”

Section: Progress Toward Cathode System In a Metal–sulfur Interacted ...mentioning

confidence: 99%

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Exploration of the Unique Structural Chemistry of Sulfur Cathode for High‐Energy Rechargeable Beyond‐Li Batteries

Sungjemmenla

Soni

Vineeth

et al. 2021

Adv Energy and Sustain Res

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The increased demand for energy has prompted users to seek alternative energy storage devices. Post‐Li‐ion battery chemistries have been considered potential contenders for the development of next‐generation battery technologies. The high specific capacity (≈1675 mAh g−1) and high natural abundance (≈953 ppm) of sulfur provide opportunities to meet the rigorous requirements of the market's demands, such as high energy density and low cost. When combined with a high capacity metal anode (e.g., Na ≈ 1165 mAh g−1, Mg ≈ 2205 mAh g−1, and Al ≈2980 mAh g−1), it leads to high energy density that can outperform the existing battery technologies, including high‐energy Li‐ion batteries. Despite the unique attributes of the sulfur‐based battery system, it remains in infancy owing to the complex reaction chemistry of sulfur cathode, and the level of complexity increases with an increase in valency of metal ions. This review summarizes the unique aspects of a sulfur cathode essential to stabilizing sulfur cathode‐based high‐energy rechargeable batteries. Furthermore, deeper insight into the electrochemical performance of various metal–sulfur‐based systems has been provided. This review may pave the path for the researchers to accelerate the development of sulfur cathode for post‐Li‐ion batteries.

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Strategies for Realizing Rechargeable High Volumetric Energy Density Conversion‐Based Aluminum–Sulfur Batteries

Zhang

Jia

et al. 2023

Adv Funct Materials

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Aluminum–sulfur batteries (ASBs) are deemed to be alternatives to meet the increasing demands for energy storage due to their high theoretical capacity, high safety, low cost, and the rich abundances of Al and S. However, the challenging problems including sluggish conversion kinetics, inferior electrolyte compatibility, and potential dendrite formation are still remained. This review comprehensively focuses on summarizing the specific strategies from polysulfide shuttling inhibition to form smooth anodic Al activation/deposition. Especially, innovations in cathodic side for achieving electrochemical kinetic modulations, electrolyte optimizations, and anodic interface mediations are discussed. Upon detailed elaborating the formation process, influencing factors, and their interactions in the Al–S electrochemistry, a comprehensive summary of their causative mechanisms and the corresponding strategies are provided, including optimization of electrolytes, innovative in situ detections, and precise electrocatalytic strategies. Based on such a systematic understanding in the Al–S electrochemistry, the possible electrochemical reaction mechanism is deciphered more clearly and enlightened practical strategies on the future development of stable ASBs. Furthermore, future opportunities and directions of high‐performance conversion‐based Al–S batteries for large‐scale energy storage applications are highlighted.

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Superior anchoring effect of a Cu-benzenehexathial MOF as an aluminium–sulfur battery cathode host

Abstract: A Cu-BHT MOF as a suitable cathode host for aluminium–sulfur batteries.

Cited by 22 publications

References 81 publications

Unraveling the Anchoring Effect of MXene-Supported Single Atoms as Cathodes for Aluminum–Sulfur Batteries

Unraveling the Anchoring Effect of MXene-Supported Single Atoms as Cathodes for Aluminum–Sulfur Batteries

Exploration of the Unique Structural Chemistry of Sulfur Cathode for High‐Energy Rechargeable Beyond‐Li Batteries

Strategies for Realizing Rechargeable High Volumetric Energy Density Conversion‐Based Aluminum–Sulfur Batteries

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