Performance study of magnesium–sulfur battery using a graphene based sulfur composite cathode electrode and a non-nucleophilic Mg electrolyte

Vinayan, B. P.; Zhao‐Karger, Zhirong; Diemant, Thomas; Chakravadhanula, Venkata Sai Kiran; Schwarzburger, Nele I.; Cambaz, Musa Ali; Behm, R. Jürgen; Kübel, Christian; Fichtner, Maximilian

doi:10.1039/c5nr04383b

Cited by 263 publications

(233 citation statements)

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“…The fore-mentioned processes correspond to the reduction of the solid cyclo-S 8 to dissolved polysulfide MgS 8 (which is subsequently reduced to MgS 6 and then to MgS 4 ), MgS 4 to solid MgS 2 , and then MgS 2 to MgS. 8,14 The first charge curve exhibits a voltage plateau at 1.3 V and a sloping voltage profile from 1.6 V to 1.7 V, which correspond to the conversion of MgS/MgS 2 to low-order polysulfuides and further to high-order polysulfuides or sulfur. In the following discharge curves, the stable voltage plateau at 1.1 V for main capacity contribution shortens obviously.…”

Section: Resultsmentioning

confidence: 99%

“…13 On the other hand, some efforts have also been made to address the dissolution of magnesium polysufide (MgS x , x ≥ 4) by using a sulfur-carbon composite 8,11,14 or fabricating new elemental selenium (Se) and selenium-sulfur solid solution (SeS 2 ) cathodes to physically restrain polysulfides, facilitate electron transport, and provide free-space to accommodate the volume change in S/polysulfides.…”

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confidence: 99%

“…12 Furthermore, a non-nucleophilic Mg electrolyte based on (HMDS) 2 Mg that uses lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) as an additive was proposed to improve the reversibility of Mg/S batteries by activating inactive MgS and MgS 2 through Li + . 13 On the other hand, some efforts have also been made to address the dissolution of magnesium polysufide (MgS x , x ≥ 4) by using a sulfur-carbon composite 8,11,14 or fabricating new elemental selenium (Se) and selenium-sulfur solid solution (SeS 2 ) cathodes to physically restrain polysulfides, facilitate electron transport, and provide free-space to accommodate the volume change in S/polysulfides. 15 This study reported on the feasibility of a sulfur cathode in a typical nucleophilic electrolyte, (PhMgCl) 2 -AlCl 3 /THF, 16 which is easily prepared and possesses high anodic stability and reversibility of Mg deposition-dissolution, by simply using Cu as the cathode current collector.…”

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Application of a Sulfur Cathode in Nucleophilic Electrolytes for Magnesium/Sulfur Batteries

Zeng

Wang

Yang

et al. 2017

J. Electrochem. Soc.

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We report the potential feasibility of a high-capacity and low-cost sulfur cathode that is compatible with nucleophilic electrolytes for Mg/S batteries. The electrochemical performance of sulfur in an easily prepared (PhMgCl) 2 -AlCl 3 /THF nucleophilic electrolyte depends on cathode current collectors. A sulfur cathode that uses Cu as a current collector, which is electrochemically stable in the range of operating voltage, exhibits an initial discharge capacity approximately corresponding to 659 mAh g −1 , and maintains a reversible capacity of 113 mAh g −1 after 20 cycles at a current density of 10 mA g −1 . It is different from the sulfur cathode with few capacities that uses stainless-steel as a current collector. Copper sulfides formed when sulfur is coated on a Cu current collector at 50 • C provide a strong chemical interaction between Cu and sulfur, which protects sulfur and increases its compatibility with the electrolyte. A metal-stabilized sulfur cathode provides an effective approach to improve the electrochemical performance of Mg/S batteries in nucleophilic electrolytes. There is a constant increase in the demand for low-cost, highenergy-density rechargeable batteries that utilize environmentally friendly elements for applications, such as market-competitive electric vehicles and large-scale power storage systems due to fossil energy shortage and environmental issues. Following the rapid development of electric vehicles with space available to mount battery packs, it is now necessary for batteries to possess good safety characteristics 1 and high volumetric energy density, which is more important than gravimetric energy density.2 Rechargeable magnesium batteries with magnesium as the anode may correspond to superior candidates compatible with post Li-ion batteries that contain a lithium metal anode, which provides a volumetric capacity (2062 mAh cm −3 ) exceeding that of a current graphite anode (777 mAh cm −3 ), 2 due to a relatively lower price ($2700 and $64800/ton for Mg and Li, respectively), 2,3 a higher theoretical volumetric capacity (3832 mAh cm −3 ), 2 and higher expected safety (the dendritic morphologies for magnesium deposits are lower than that for lithium). 4 Muldoon et al. first suggested an electrophilic sulfur cathode candidate with a high theoretical capacity (1671 mAh g −1 or 3459 mAh cm −3 ) corresponding to a conversion class as opposed to an insertion class. It is chemically incompatible with nucleophilic magnesium organohaloaluminate electrolytes and compatible with a non-nucleophilic electrolyte based on a recrystallized Mg complex [Mg 2 (μ-Cl) 3 (THF) 6 ][HMDSAlCl 3 ] formed from a reaction between hexamethyldisilazide magnesium chloride (HMDSMgCl) and AlCl 3 (3:1 molar ratio) in tetrahydrofuran (THF).2,4 The magnesium/sulfur (Mg/S) batteries yield a theoretical volumetric energy density exceeding 4000 Wh L −1 as compared to 2800 Wh L −1 for lithium/sulfur (Li/S) batteries.5 However, on cycling, Mg/S batteries also suffer from capacity fading, which results from low active...

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Section: Resultsmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Application of a Sulfur Cathode in Nucleophilic Electrolytes for Magnesium/Sulfur Batteries

Zeng

Wang

Yang

et al. 2017

J. Electrochem. Soc.

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“…10(a)]. Interestingly, the overcharging behavior is much less significant compared with the previous [29,32] 3.9 ∼2 ∼100 Yes 260@20/20 [32] 1000@71/30 [33] 236@20/50 [34] 800@167/20 [ [47,53] 3.1 [47] , 2.5 [53] 2 [47] , 8.5 [53] 99 Yes 70@17/20 [53] Mg(TFSI) 2 Prospective Article reports and an overpotential during charge and discharge was <0.4 V. The Mg-S cells were cycled for 30 times with capacity retention >86% [ Fig. 10(b)].…”

Section: Conductive Salt-based Electrolytesmentioning

confidence: 88%

“…This is the obvious reason for the superior electrochemical performance when compared with the electrolyte generated from HMDSMgCl-AlCl 3 containing several anionic species in form HMDS n AlCl 4−n − (n = 1-3). [28] Owing to the favorable electrochemical and chemical properties and its simplicity in preparation, this type of electrolyte has been employed in different Mg battery systems with both intercalation and conversion cathodes, including Mo 6 S 8 , [29] vanadium oxychloride (VOCl), [31] S, [32][33][34][35] Se, [36] and iodine. [37] Fluorinated alkoxide-based electrolytes…”

Section: Non-nucleophilic Magnesium Electrolytes Hauser Base-based Elmentioning

confidence: 99%

Magnesium-sulfur battery: its beginning and recent progress

Zhao‐Karger

Fichtner

2017

MRS Communications

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Rechargeable magnesium (Mg) battery has been considered as a promising candidate for future battery generations because of its potential high-energy density, its safety features and low cost. The challenges lying ahead for the realization of Mg battery in general are to develop proper electrolytes fulfilling a multitude of requirements and to discover cathode materials enabling high-energy Mg batteries. The combination of Mg anode with a sulfur cathode is one of the promising electrochemical couples due to its advantages of safety, low costs, and a high theoretical energy density of over 3200 Wh/L. However, the research on magnesium-sulfur (Mg-S) battery is just at its beginning and the development of suitable electrolytes has been the key challenge for further improvement, and, thus, in the focus of recent research. In this review, we highlight the recent progress achieved in Mg electrolytes and Mg-S batteries and discuss the major technical issues, which must be resolved for the improvement of Mg-S batteries.

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Applications of Graphene

Spasenović¹

2020

Surface and Interface Science

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Performance study of magnesium–sulfur battery using a graphene based sulfur composite cathode electrode and a non-nucleophilic Mg electrolyte

Cited by 263 publications

References 45 publications

Application of a Sulfur Cathode in Nucleophilic Electrolytes for Magnesium/Sulfur Batteries

Application of a Sulfur Cathode in Nucleophilic Electrolytes for Magnesium/Sulfur Batteries

Magnesium-sulfur battery: its beginning and recent progress

Applications of Graphene

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