Anionic Se‐Substitution toward High‐Performance CuS 1− x Se x Nanosheet Cathode for Rechargeable Magnesium Batteries

Wang

Advanced Energy Materials

et al. 2020

162

117

Rechargeable magnesium batteries (RMBs), which have attracted tremendous attention in large‐scale energy storage applications beyond lithium ion batteries, have many advantages such as high volumetric capacity, low cost, and environmental friendliness. However, the strong polarization effect, slow kinetic de‐intercalation of Mg2+ ions, and the incompatibility between electrodes and electrolytes limit their commercial application. Thus, developing stable and high‐efficiency electrode materials and optimization of electrolytes are key to promoting the practical application of RMBs. In this review, a summary and discussion are provided regarding the recent progress in the development of the key materials for RMBs, including cathodes, anodes, and electrolytes. The cathode materials including intercalation type cathodes and conversion type cathodes are classified and introduced in detail by the reaction mechanism, the effects of structure on the kinetics of Mg2+ ion migration are clarified; the modification and interface issues of Mg anode materials are comprehensively stated, and the potential development prospects of RMB electrolytes are systematically analyzed. In addition, the main opportunities and challenges in this field are briefly elaborated and discussed. Finally, this review will provide a framework for the key materials for RMBs as a reference for future research.

Section: Cathodesmentioning

confidence: 99%

Challenges and Recent Progress on Key Materials for Rechargeable Magnesium Batteries

Wang

Advanced Energy Materials

et al. 2020

162

117

“…[11] Recently, the Mg battery research community has turned its attention toward metal chalcogenides as potential cathode materials (Figure 1b). [12][13][14][15][16][17][18][19][20][21][22][23][24][25][26] Up until 2017, research on metal chalcogenide cathodes has been primarily based on Mo 6 S 8 , which is widely used as the standard cathode material for evaluating new electrolyte systems and/or new cathode materials. A sudden change in trend is noticed when the number of publications reporting on other metal chalcogenides has increased significantly over the past 3 years.…”

Section: The Emergence Of Rechargeable Magnesium Batteries (Rmbs)mentioning

confidence: 99%

“…[5,15,[33][34][35] Recent publications have also shown the benefits of nanostructuring of metal chalcogenides in improving battery performance as a consequence of increased surface area and shortened diffusion path for Mg 2+ ion in solid phase. [12,14,16,21] To our knowledge, however, no review has been done on the impact of nanostructure engineering of metal chalcogenide cathodes on RMB performance, prompting us to give a succinct review on the application of nanostructured metal chalcogenides for RMBs. This review, nevertheless, will also be beneficial to the development of advanced cathode materials for other emerging battery systems, such as sodium, calcium, and aluminum batteries, which are rapidly gaining much interest from the battery research community.…”

Section: The Emergence Of Rechargeable Magnesium Batteries (Rmbs)mentioning

confidence: 99%

“…[53] In addition, the conversion cathode exhibits large voltage hysteresis observed between discharge and charge, which results in low energy efficiency. [53,54] The metal chalcogenides that have been experimentally attempted as conversion cathode for Mg batteries are CuS, [14,17,18,[23][24][25][26]34,[55][56][57][58] Ag 2 S and Ag 2 Se, [15,19,59] NiCo 2 Se 4 , [28] Cu 2−x Se, [13] CuSe, [60] Ni 0.85 Se, [61] CuS 1−x Se x , [16] CoS, [62] FeS 2, [63] Sb 2 Se 3 , [20] Bi 2 Se 3 , [20] CoSe 2 , [21] and Ni 0.75 Fe 0.25 Se 2.…”

Section: Types and Structures Of Metal Chalcogenide Cathodesmentioning

confidence: 99%

“…In comparing the electrochemical properties of mixedanion CuS 1−x Se x with those of CuS, Wang et al have found that Se-substitution can lead to better Mg-ion storage performance by improving the conversion-type reaction kinetics. [16] This is because Se can enhance the net electronic conductivity and lower the Mg-ion migration barrier, which can accelerate the conversion reaction rates. For similar reasons, promising Mg-ion storage behavior was also observed when binary Cu 2−x Se phases were employed as cathodes.…”

Section: Copper Chalcogenidesmentioning

confidence: 99%

See 2 more Smart Citations

Designing Nanostructured Metal Chalcogenides as Cathode Materials for Rechargeable Magnesium Batteries

Regulacio

Nguyen

Horia

et al. 2021

Small

Rechargeable magnesium batteries (RMBs) are regarded as promising candidates for beyond‐lithium‐ion batteries owing to their high energy density. Moreover, as Mg metal is earth‐abundant and has low propensity for dendritic growth, RMBs have the advantages of being more affordable and safer than the currently used lithium‐ion batteries. However, the commercial viability of RMBs has been negatively impacted by slow diffusion kinetics in most cathode materials due to the high charge density and strongly polarizing nature of the Mg2+ ion. Nanostructuring of potential cathode materials such as metal chalcogenides offers an effective means of addressing these challenges by providing larger surface area and shorter migration routes. In this article, a review of recent research on the design of metal chalcogenide nanostructures for RMBs’ cathode materials is provided. The different types and structures of metal chalcogenide cathodes are discussed, and the synthetic strategies through which nanostructuring of these materials can be achieved are described. An organized summary of their electrochemical performance is also presented, along with an analysis of the current challenges and future directions. Although particular focus is placed on RMBs, many of the nanostructuring concepts that are discussed here can be carried forward to other next‐generation energy storage systems.

Pulverization‐Tolerant CuSe Nanoflakes with High (110) Planar Orientation for High‐Performance Magnesium Storage

Zhang

Zhu

Wang

et al. 2021

Adv Funct Materials

Self Cite

Copper chalcogenides are of great interest as conversion-type cathode materials due to their large specific capacity for rechargeable magnesium batteries, yet are subjected to severe capacity fading brought about by structure collapse in repetitive charge-discharge cycling. Herein, single-crystalline and (110) preferentially oriented CuSe nanoflakes are designed via a temperaturecontrolled crystal growth route under microwave irradiation. The as-prepared CuSe nanoflake cathode materials can present high reversible capacity (204 mAh g −1 at 200 mA g −1 current density), outstanding rate capability, and remarkable long-term cycling stability (≈0.095% capacity decay per cycle at 1 A g −1 within 700 cycles). The multistep reversible conversion mechanism of the CuSe nanoflake cathode materials is evidenced by ex situ X-ray photoelectron spectroscopy and X-ray diffraction. Structure evolution investigation suggests that the single-crystalline CuSe nanoflakes can exhibit relatively durable structural stability. The desirable cycling stability can be ascribed to the excellent pulverization-tolerance of the CuSe nanoflake cathode materials endowed by the multistep reversible conversion mechanism and the single-crystalline feature. Furthermore, the preferentially-oriented (110) active plane is favorable for electrochemical reactions to ensure high specific capacity. This work can afford a crystal engineering strategy to fabricate high-performance conversion-type electrode materials for rechargeable magnesium batteries.