To Be or Not to Be – Is MgSc<sub>2</sub>Se<sub>4</sub> a Mg‐Ion Solid Electrolyte?

Glaser, Clarissa; Wei, Zhixuan; Indris, Sylvio; Klement, Philip; Chatterjee, Sangam; Ehrenberg, Helmut; Zhao‐Karger, Zhirong; Rohnke, Marcus; Janek, Jürgen

doi:10.1002/aenm.202301980

Cited by 7 publications

(2 citation statements)

References 44 publications

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“…Erstmals haben Janek und Mitarbeitende den Mg 2+ -Transport in MgSc 2 Se 4 auf zwei Wegen nachgewiesen: durch elektrochemische Abscheidung elementaren Magnesiums und durch reversible Magnesiumgalvanisierung und -entschichtung. 23) Die beobachtete niedrige Migrationsbarriere (386 ± 24 meV) führt zu einer der besten Leistungen bei Raumtemperatur unter den bekannten anorganischen Magnesiumfestelektrolyten.…”

Section: Aus Dem Labor: Synthesemethodenunclassified

Trendbericht Festkörperchemie und Materialforschung 2024

Rasche,

Schwartz

2024

Nachr Chem

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Schwerpunkte sind die Effizienz von Synthesen, deren Nachhaltigkeit oder Materialien für eine CO2‐emissionsärmere Zukunft. Neben der gesellschaftlichen Dringlichkeit, hervorgerufen durch den Klimawandel, ist dieser Umschwung dadurch motiviert, dass Drittmittel vor allem für Anwendungsforschung vergeben werden. Bei dieser lösungsorientierten Festkörperforschung verschmelzen klassische Chemie, Physik und Materialwissenschaften. Dennoch bleiben Grundlagenthemen essenziell.

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Section: Aus Dem Labor: Synthesemethodenunclassified

Trendbericht Festkörperchemie und Materialforschung 2024

Rasche,

Schwartz

2024

Nachr Chem

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“…The room temperature (RT) ionic conductivity of borohydride materials can reach up to 10 −5 S cm −1 with such ligand substitution, [ 22 ] yet further conductivity enhancement is necessary for RT battery operation. The spinel chalcogenide MgSc 2 Se 4 which was first reported in 2017 [ 17 ] and recently further confirmed, [ 23 ] has some of the highest RT Mg‐ion conductivity of 0.1 mS cm −1 , but is hampered by a high intrinsic electronic conductivity.…”

Section: Introductionmentioning

confidence: 94%

Fast Room‐Temperature Mg‐Ion Conduction in Clay‐Like Halide Glassy Electrolytes

Yang,

Gupta,

Chen

et al. 2024

Advanced Energy Materials

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The discovery of mechanically soft solid‐state materials with fast Mg‐ion conduction is crucial for the development of solid‐state magnesium batteries. In this paper, novel magnesium gallium halide compounds are reported that achieve high ionic conductivity of 0.47 mS cm−1 at room temperature. These Mg‐ion conductors obtained by ball milling Mg and Ga salts exhibit clay‐like mechanical properties, enabling intimate contact at the electrode–electrolyte interface during battery cycling. With a combination of experimental and computational analysis, this study identifies that the soft‐clay formation is induced by partial anion exchange during milling. This partial anion exchange creates undercoordinated magnesium ions in a chlorine‐rich environment, yielding fast Mg‐ion conduction. This work demonstrates the potential of clay‐like halide electrolytes for all‐solid‐state magnesium batteries, with possible further extension to other multivalent battery systems.

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Challenges and Progress in Anode‐Electrolyte Interfaces for Rechargeable Divalent Metal Batteries

Wang,

Riedel,

Zhao‐Karger

2024

Advanced Energy Materials

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Divalent metal batteries have attracted considerable attention in scientific exploration for sustainable energy storage solutions owing to the abundant reserves of magnesium (Mg) and calcium (Ca), the competitive low redox potentials of the Mg/Mg2+ (–2.37 V vs SHE) and Ca/Ca2+ (–2.87 V vs SHE) couples, as well as the high theoretical capacities of both metal anodes. However, the development of these batteries faces fundamental challenges stemming from the limited cycling stability and efficiency of Mg/Ca metal anodes. These issues primarily originate from the sluggish electrochemical redox kinetics of the divalent metals, particularly at the anode‐electrolyte interfaces. This comprehensive review provides an up‐to‐date overview of advancements in the field of the anode‐electrolyte interface for divalent metal batteries, covering aspects ranging from its formation, morphology, and composition to their influence on the reversible electrochemical deposition of divalent metals. Recent approaches aimed at enhancing the performance of metallic Mg and Ca anodes across various electrolytes are summarized and discussed, with the goal of providing insights for the development of new strategies in future research.

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To Be or Not to Be – Is MgSc₂Se₄ a Mg‐Ion Solid Electrolyte?

Cited by 7 publications

References 44 publications

Trendbericht Festkörperchemie und Materialforschung 2024

Trendbericht Festkörperchemie und Materialforschung 2024

Fast Room‐Temperature Mg‐Ion Conduction in Clay‐Like Halide Glassy Electrolytes

Challenges and Progress in Anode‐Electrolyte Interfaces for Rechargeable Divalent Metal Batteries

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To Be or Not to Be – Is MgSc2Se4 a Mg‐Ion Solid Electrolyte?

Cited by 7 publications

References 44 publications

Trendbericht Festkörperchemie und Materialforschung 2024

Trendbericht Festkörperchemie und Materialforschung 2024

Fast Room‐Temperature Mg‐Ion Conduction in Clay‐Like Halide Glassy Electrolytes

Challenges and Progress in Anode‐Electrolyte Interfaces for Rechargeable Divalent Metal Batteries

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To Be or Not to Be – Is MgSc₂Se₄ a Mg‐Ion Solid Electrolyte?