Boron Clusters as Highly Stable Magnesium‐Battery Electrolytes

Carter, Tyler J.; Mohtadi, Rana; Arthur, Timothy S.; Mizuno, Fuminori; Zhang, Ruigang; Shirai, Soichi; Kampf, Jeff W.

doi:10.1002/ange.201310317

Cited by 74 publications

(62 citation statements)

References 30 publications

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“…[41][42][43] These studies showed that modified structures would lead to high magnesium plating efficiencies with higher potential windows. After the first introduction of ar eversible magnesium battery,m any studies concerning magnesium organoaluminates and organoborates have been reported.…”

Section: Magnesiummentioning

confidence: 99%

“…After the first introduction of ar eversible magnesium battery,m any studies concerning magnesium organoaluminates and organoborates have been reported. [41][42][43] These studies showed that modified structures would lead to high magnesium plating efficiencies with higher potential windows. However,f or battery development, it is necessary to find as impler salt/electrolyte combination with high performance because the organosalts of magnesium are too expensive for real applications.T he first inorganic salt tested for am agnesium battery electrolyte was Mg(BH 4 ) 2 .…”

Section: Magnesiummentioning

confidence: 99%

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Electrolytes for Batteries with Earth‐Abundant Metal Anodes

Zhao

Yin

et al. 2018

Chemistry A European J

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Earth-abundant metal anodes have become one of the hottest topics in recent years. As alternatives to lithium metals, earth-abundant metal anodes have significantly lower cost and higher energy density, but with unprecedented problems that cannot be solved by simply referring to experiences with lithium-metal anodes. The electrolytes for these anodes greatly influence the overall performance, such as Coulombic efficiency, stability, and even the availability to become an anode. In this Minireview, some excellent state-of-art works on the electrolytes of energy-storage systems with sodium-, potassium-, magnesium-, calcium-, and aluminum-metal anodes are concisely summarized. The performance of these systems is highlighted by the rational design of the electrolyte and electrolyte/electrode interface.

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Section: Magnesiummentioning

confidence: 99%

Section: Magnesiummentioning

confidence: 99%

Electrolytes for Batteries with Earth‐Abundant Metal Anodes

Zhao

Yin

et al. 2018

Chemistry A European J

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“…In particular electrolytes based on magnesium borohydride, Mg(BH 4 ) 2 , have received significant attention since 2012, when Mohtadi et al . demonstrated the first fully inorganic and halide-free Mg electrolytes enabling reversible Mg plating and stripping78. In an effort to improve the safety, attempts have been made to replace the flammable organic solvents by ionic liquids91011.…”

mentioning

confidence: 99%

Magnesium Ethylenediamine Borohydride as Solid-State Electrolyte for Magnesium Batteries

Roedern

Kühnel

Remhof

et al. 2017

Sci Rep

128

163

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Solid-state magnesium ion conductors with exceptionally high ionic conductivity at low temperatures, 5 × 10−8 Scm−1 at 30 °C and 6 × 10−5 Scm−1 at 70 °C, are prepared by mechanochemical reaction of magnesium borohydride and ethylenediamine. The coordination complexes are crystalline, support cycling in a potential window of 1.2 V, and allow magnesium plating/stripping. While the electrochemical stability, limited by the ethylenediamine ligand, must be improved to reach competitive energy densities, our results demonstrate that partially chelated Mg2+ complexes represent a promising platform for the development of an all-solid-state magnesium battery.

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“…z E-mail: kthorn@umich.edu their practical application in batteries. 14 To avoid this problem, inorganic salts such as Mg(TFSI) 2 and Mg(BH 4 ) 2 in solutions based on traditional solvents 10,[15][16][17][19][20][21] or ionic liquids [22][23][24]26 have also been explored.Despite the recent growth in efforts to develop efficient magnesium electrolytes, many challenges remain. For example, formation of ionblocking passivation films on magnesium surfaces and compatibility with cathode materials (allowing reversible intercalation of Mg 2+ ) both remain challenges.…”

mentioning

confidence: 99%

“…2,7,8,11,12,27 Due to their halide content, Grignards, organohaloaluminates, and MACC are corrosive to non-noble metal substrates, which presents a challenge to their practical application in batteries. 14 To avoid this problem, inorganic salts such as Mg(TFSI) 2 and Mg(BH 4 ) 2 in solutions based on traditional solvents 10,[15][16][17][19][20][21] or ionic liquids [22][23][24]26 have also been explored.…”

mentioning

confidence: 99%

Computational Model of Magnesium Deposition and Dissolution for Property Determination via Cyclic Voltammetry

Chadwick

Vardar

DeWitt

et al. 2016

J. Electrochem. Soc.

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The development of a practical magnesium-anode battery requires electrolytes that allow for highly efficient magnesium exchange while also being compatible with cathode materials. Here, a one-dimensional continuum-scale model is developed to simulate cyclic plating/stripping voltammetry of a model magnesium-based electrolyte system employing magnesium borohydride/dimethoxyethane [Mg(BH 4 ) 2 /DME] solutions on a gold substrate. The model is developed from non-electroneutral dilute-solution theory, using Nernst-Planck equations for the mass flux and Poisson's equation for the electrostatic potential. The electrochemical reaction is modeled with multistep Butler-Volmer kinetics, with a modified current/overpotential relationship that separately accounts for the portions of the current responsible for nucleating new deposits and propagating or dissolving existing ones. The diffusivities of the electrolyte species, standard heterogeneous rate constant, charge-transfer coefficient, formal potential, and nucleation overpotential are determined computationally by reproducing experimental voltammograms. The model is computationally inexpensive and therefore allows for broad parametric studies of electrolyte behavior that would otherwise be impractical. A rechargeable magnesium battery was first demonstrated 25 years ago when Gregory et al. 1 showed that magnesium could be reversibly deposited onto and dissolved from a magnesium-metal surface, as well as intercalated into and deintercalated from various host cathodes. Further interest in secondary magnesium batteries arose following the work of Aurbach et al., 2 which demonstrated a highly efficient organohaloaluminate electrolyte using a magnesium anode and a Mo 6 S 8 Chevrel-phase cathode. As a battery anode, magnesium metal offers important advantages over both intercalation compounds and lithium metal, including a higher theoretical volumetric energy capacity (3833 mAh/cm 3 vs. 2046 mAh/cm 3 for lithium metal and 760 mAh/cm 3 for graphite-based lithium-ion anodes), as well as a higher abundance in the earth's crust.3 Additionally, magnesium is less prone to dendrite formation than lithium when electrodeposited and therefore offers potential for improved battery cycle life and safety. 4 In addition to high-capacity electrode materials, a practical magnesium battery will also require an efficient electrolyte that is compatible with (i.e., chemically stable in contact with) these electrodes. Compared to lithium electrolytes, magnesium electrolytes remain in a relatively early developmental stage.1-29 Electrolytes formulated from Grignard reagents have been widely studied both in the battery and general electrochemistry communities. 1,6,28,[30][31][32][33][34][35] The speciation of these electrolytes is complex because, in addition to ionic dissociation, the reagents also undergo the Schlenk equilibrium process (a type of ligand exchange) and form multimeric species in many solvents. Both organohaloaluminates and the so-called magnesium aluminum chloride complex (MACC) a...

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Boron Clusters as Highly Stable Magnesium‐Battery Electrolytes

Cited by 74 publications

References 30 publications

Electrolytes for Batteries with Earth‐Abundant Metal Anodes

Electrolytes for Batteries with Earth‐Abundant Metal Anodes

Magnesium Ethylenediamine Borohydride as Solid-State Electrolyte for Magnesium Batteries

Computational Model of Magnesium Deposition and Dissolution for Property Determination via Cyclic Voltammetry

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