Recent Advances in Rechargeable Magnesium‐Based Batteries for High‐Efficiency Energy Storage

Guo, Zhen; Zhao, Shuoqing; Li, Tiexin; Su, Dawei; Guo, Shaojun; Wang, Guoxiu

doi:10.1002/aenm.201903591

Cited by 148 publications

(102 citation statements)

References 156 publications

(181 reference statements)

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“…Benefited from this unique structure, about two Mg 2+ ions can be intercalated into each formula unit. [103] Moreover, the micro-sized Mo 6 S 8 also can deliver outstanding Mg ions storage performance when used as practical cathode material for RMBs. [40,104] Figure 2b shows the voltage profile with the intercalation of Mg 2+ into Mo 6 S 8 .…”

Section: Doping Ionsmentioning

confidence: 99%

Recent Progress and Challenges in the Optimization of Electrode Materials for Rechargeable Magnesium Batteries

Pei

Xiong

Yin

et al. 2020

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Rechargeable magnesium batteries (RMBs) have been regarded as one of the promising electrochemical energy storage systems to complement Li‐ion batteries owing to the low‐cost and high safety characteristics. However, the various challenges including the sluggish solid‐state diffusion of highly polarizing Mg2+ ions in hosts, and the formation of blocking layers on Mg metal surface have seriously impeded the development of high‐performance RMBs. In order to solve these problems toward practical applications of RMBs, a tremendous amount of work on electrodes and electrolytes has been conducted in the last few decades. Creative optimization strategies including the modification of cathodes and anodes such as shielding the charges of divalent Mg2+, expanding the layers of host materials, and optimizing the interface of electrode–electrolyte are raised to promote the technology. In this review, the detailed description of innovative approaches, representative examples, and facing challenges for developing high‐performance electrodes are presented. Based on the review of these strategies, guidelines are provided for future research directions on improving the overall battery performance, especially on the electrodes.

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Section: Doping Ionsmentioning

confidence: 99%

Recent Progress and Challenges in the Optimization of Electrode Materials for Rechargeable Magnesium Batteries

Pei

Xiong

Yin

et al. 2020

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“…Despite the straightforward concept of taking advantage of a divalent cation, developing rechargeable and stable MIBs has been plagued by various materials limitations, especially the lack of suitable intercalation electrode materials and stable electrolytes featuring wide electrochemical windows. [ 12–15 ] Indeed, the greatest of these limitations on simulating the working mechanism of LIBs using intercalation cathodes and anodes is primarily caused by the sluggish solid‐state diffusion of divalent Mg ion. This is strongly related to the large polarization of anionic frameworks of electrodes and more intense repulsions among the intercalated divalent Mg ions due to a higher charge‐to‐radius ratio of Mg 2+ compared to Li + .…”

Section: Figurementioning

confidence: 99%

Hydrated Mg_xV₅O₁₂ Cathode with Improved Mg²⁺ Storage Performance

Zhu

Huang

Yin

et al. 2020

Advanced Energy Materials

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Li + (0.76 Å) holds a great potential to deliver remarkable theoretical energy storage metrics. [10,11] Despite the straightforward concept of taking advantage of a divalent cation, developing rechargeable and stable MIBs has been plagued by various materials limitations, especially the lack of suitable intercalation electrode materials and stable electrolytes featuring wide electrochemical windows. [12-15] Indeed, the greatest of these limitations on simulating the working mechanism of LIBs using intercalation cathodes and anodes is primarily caused by the sluggish solid-state diffusion of divalent Mg ion. This is strongly related to the large polarization of anionic frameworks of electrodes and more intense repulsions among the intercalated divalent Mg ions due to a higher charge-to-radius ratio of Mg 2+ compared to Li +. [16-18] Because of heavy anionic frameworks and moderate polarity of anions, the classical Mo 6 S 8 Chevrel phases and transition metal dichalcogenides show an Mg 2+ screening effect, [19,20] mitigating the solid-state diffusion difficulty of Mg 2+ to some extent. However, the facilitation of Mg 2+ diffusion within these electrode frameworks comes at the cost of average operating potentials (≈1 V vs Mg/Mg 2+) and gravimetric capacities, thus leading to low energy densities. [21,22] Noticeably, the low redox potential feature of these chalcogenide electrodes reveals that they are anodes virtually upon assembling to full MIBs, if cathodes with high operating potentials are applied. Switching to transition metal oxide electrodes can fundamentally elevate operating potentials and increase specific capacities. [20,23-25] Nonetheless, the bivalency nature of Mg 2+ imposes a large energy penalty during the desolvation process at the electrode/electrolyte interface, resulting in insufficient power densities. To improve the rate capability, nanostructure engineering (e.g., increasing interlayer spacing of layered electrodes) and chemical composition control (e.g., structural H 2 O, cation doping) of oxide electrodes can be conducted to modify the kinetics and thermodynamics of Mg 2+ insertion. [26-28] Orthorhombic single-layered V 2 O 5 , consisting of alternating corner-and edge-sharing VO 5 square pyramids (Figure S1, Supporting Information), allows the diffusion of small, monovalent Li ions through the framework. However, the limited interlayer spacing of ≈4.5 Å is not sufficient for the intercalation of larger (e.g., Na +) or multivalent (e.g., Mg 2+) cations. [7,29,30] Employing single-layered V 2 O 5 to design bilayered vanadium bronzes through different chemical approaches enables the applicability Mg-ion batteries (MIBs) possess promising advantages over monovalent Li-ion battery technology. However, one of the myriad obstacles in realizing highly efficient MIBs is a limited selection of cathode materials that can enable reversible, stable Mg 2+ intercalation at a high operating voltage. Here, a scalable method is showcased to synthesize a hydrated Mg x V 5 O 12 cathode, which shows a high capa...

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“…[ 1 ] In order to meet the demand for energy storage market, exploitation of alternative energy storage systems with long‐term sustainability, cost‐effectiveness, and high energy density is quite urgent and important, such as sodium ion batteries, [ 2 ] sodium–sulfur batteries, [ 3 ] potassium ion batteries (PIBs), [ 4 ] zinc ion batteries, [ 5 ] aluminum ion batteries, [ 6 ] and magnesium ion batteries. [ 7 ] In very recent years, potassium, which lies in the same group with lithium, begins to come into scientists’ view due to their unique advantages. [ 8 ] Relatively high abundance of potassium element (1.5 wt%) can lead to its lower‐cost refinement than that of lithium while its widespread distribution both on the earth's crust and in the oceans also contributes to broader accessible pathways.…”

Section: Introductionmentioning

confidence: 99%

Advanced High‐Performance Potassium–Chalcogen (S, Se, Te) Batteries

Huang

Sun

Wang

et al. 2021

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Current great progress on potassium‐chalcogen (S, Se, Te) batteries within much potential to become promising energy storage systems opens a new avenue for the rapid development of potassium batteries as a complementary option to lithium ion batteries. The discussion mainly concentrates on recent research advances of potassium–chalcogen (S, Se, Te) batteries and their corresponding cathode materials in this review. Initially, the development of cathode materials for four types of batteries is introduced, including: potassium–sulfur (K–S), potassium–selenium (K–Se), potassium–selenium sulfide (K–SexSy), and potassium–tellurium (K–Te) batteries. Next, critical challenges for chalcogen‐based electrodes in devices operation are summarized. In addition, some pragmatic strategies are proposed as well to relieve the low electronic conductivity, large volumetric expansion, shuttle effect, and potassium dendrite growth. At last, the perspectives on designing advanced cathode materials for potassium–chalcogen batteries are provided with the goal of developing high‐performance potassium storage devices.

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Recent Advances in Rechargeable Magnesium‐Based Batteries for High‐Efficiency Energy Storage

Cited by 148 publications

References 156 publications

Recent Progress and Challenges in the Optimization of Electrode Materials for Rechargeable Magnesium Batteries

Recent Progress and Challenges in the Optimization of Electrode Materials for Rechargeable Magnesium Batteries

Hydrated Mg_xV₅O₁₂ Cathode with Improved Mg²⁺ Storage Performance

Advanced High‐Performance Potassium–Chalcogen (S, Se, Te) Batteries

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Recent Advances in Rechargeable Magnesium‐Based Batteries for High‐Efficiency Energy Storage

Cited by 148 publications

References 156 publications

Recent Progress and Challenges in the Optimization of Electrode Materials for Rechargeable Magnesium Batteries

Recent Progress and Challenges in the Optimization of Electrode Materials for Rechargeable Magnesium Batteries

Hydrated MgxV5O12 Cathode with Improved Mg2+ Storage Performance

Advanced High‐Performance Potassium–Chalcogen (S, Se, Te) Batteries

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Hydrated Mg_xV₅O₁₂ Cathode with Improved Mg²⁺ Storage Performance