Intercalation-type positive electrode materials for nonaqueous calcium-ion batteries

Bu, Hyeri; Lee, Hyungjin; Setiawan, Dedy; Hong, Seung‐Tae

doi:10.1063/5.0073087

Cited by 5 publications

(4 citation statements)

References 144 publications

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“…Given concerns about the supply and sustainability of lithium (Li) ion battery components, there is growing interest in developing a beyond-Li materials basis for rechargeable batteries. , Divalent batteries based on calcium (Ca) have received growing attention due to the ∼2000-fold higher concentration of Ca than Li in the earth’s crust, lower cost than Li, and attractive theoretical cell-level metrics if Ca is used as the metallic anode (−2.87 V vs SHE, 1337 mAh/g, 2073 mAh/cm 3 ). − However, technological development of Ca batteries has been hindered by a lack of viable electrolytes for pairing with Ca anodes as well as a lack of suitable cathode materials . In nonaqueous liquid electrolytes, large coordination shells form around Ca 2+ that can include upward of 8 solvating species (compared to ∼4 for Li + ) and significant ion pairing, ,, which increases energy barriers of dissociation and/or desolvation and hinders Ca 2+ transport.…”

Section: Introductionmentioning

confidence: 99%

“…3−6 However, technological development of Ca batteries has been hindered by a lack of viable electrolytes for pairing with Ca anodes 7 as well as a lack of suitable cathode materials. 8 In nonaqueous liquid electrolytes, large coordination shells form around Ca 2+ that can include upward of 8 solvating species (compared to ∼4 for Li + ) and significant ion pairing, 3,6,9 which increases energy barriers of dissociation and/or desolvation and hinders Ca 2+ transport. At the solid electrolyte interphase (SEI), solid-state Ca 2+ migration is impeded by the cation's large ionic radius as well as poor Ca 2+ ionic conductivity of the SEI phases.…”

Section: ■ Introductionmentioning

confidence: 99%

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Impact of Differential Ca²⁺ Coordination in Borohydride-Based Electrolyte Blends on Calcium Electrochemistry and SEI Formation

Melemed,

Skiba,

Steinberg

et al. 2023

J. Phys. Chem. C

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Despite growing interest in calcium (Ca)-based batteries for sustainable energy storage, there are a limited number of electrolytes that enable the reversible plating/stripping of Ca metal. Consequently, an understanding of the interplay between electrolyte formulation, solid electrolyte interphase (SEI) composition, and electrochemical performance lags behind that of other alkali and alkaline-earth batteries. In this context, this study examines how plating/stripping behavior and SEI formation are modulated by differential changes in solvent composition and the resulting Ca 2+ −anion speciation in borohydride electrolytes comprising ether solvent blends. Starting with the baseline electrolyte 1 M Ca(BH 4 ) 2 in tetrahydrofuran (THF), THF was systematically replaced by 1,2-dimethoxyethane (G1) or bis(2-methoxyethyl) ether (G2) over a range of Gx:Ca 2+ molar ratios (0−4:1 G1:Ca 2+ or 0−3:1 G2:Ca 2+ ). Replacement of THF by glymes increased the plating overpotential and decreased the Coulombic efficiency of Ca plating/stripping, and a marked decrease in electrochemical activity occurred at a composition threshold for each glyme. Comparison between the X-ray photoelectron spectra of electrolyte-soaked Ca and electrodeposited Ca revealed a relative increase in organic C−O species and a decrease in borate species in the electrochemically-formed SEI with increased glyme proportion in the electrolyte. NMR and Raman spectroscopy connected SEI composition to differential Ca 2+ coordination, as glymes displace THF from the Ca 2+ coordination environment, weaken Ca 2+ −BH 4 − interactions, and prompt BH 4 − reorganization. Overall, BH 4 − -facilitated solvent decomposition governs Ca electrochemistry in these systems, as coordinated THF promotes beneficial borate formation but coordinated glymes limit such phases, leading to Ca 2+ -blocking phases in the SEI. These findings delineate future directions to modulate Ca(BH 4 ) 2 coordination toward improving electrolyte reversibility by considering the O-donating ability of the coordinating solvent.

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Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Impact of Differential Ca²⁺ Coordination in Borohydride-Based Electrolyte Blends on Calcium Electrochemistry and SEI Formation

Melemed,

Skiba,

Steinberg

et al. 2023

J. Phys. Chem. C

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“…Given these advantages, one key to successful CIB development is using positive electrode materials exhibiting high theoretical capacity. However, CIB cathode material development is still in its infancy; only a few materials have been reported to reversibly insert calcium ions in dried nonaqueous electrolytes to date; the mechanism of Ca insertion into host materials remains poorly understood …”

Section: Introductionmentioning

confidence: 99%

“…However, CIB cathode material development is still in its infancy; only a few materials have been reported to reversibly insert calcium ions in dried nonaqueous electrolytes to date; the mechanism of Ca insertion into host materials remains poorly understood. 12 Examination of the CIB host materials reported thus far suggests that sufficiently wide pathways should be ensured for facile migration of Ca ions. 13 Accordingly, most known cathode materials have a layered structure with wide interlayer spacing and structural flexibility.…”

Section: Introductionmentioning

confidence: 99%

(NH₄)₂V₇O₁₆ as a Cathode Material for Rechargeable Calcium-Ion Batteries: Structural Transformation and Co-Intercalation of Ammonium and Calcium Ions

Bu,

Lee,

Hyoung

et al. 2023

Chem. Mater.

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Calcium-ion batteries (CIBs) are viable alternatives to lithium-ion batteries. However, few cathode materials can reversibly intercalate Ca ions in anhydrous electrolytes. Most highcapacity materials contain crystal water, causing unwanted reactions on the anode. Herein, we report a crystal-water-free ammonium vanadate, (NH 4 ) 2 V 7 O 16 , as a CIB host material. Synthesized via a microwave-assisted hydrothermal method, (NH 4 ) 2 V 7 O 16 exhibits a layered structure with stacked V 7 O 16 layers and interlayer ammonium ions hydrogen-bonded to adjacent oxygen atoms. We demonstrate the reversible electrochemical intercalation of Ca 2+ ions into (NH 4 ) 2 V 7 O 16 , achieving a reversible capacity of 89 mA h g −1 and an average discharge voltage of ∼3.21 V vs Ca/Ca 2+ . Although (NH 4 ) 2 V 7 O 16 displays poor rate capability and cycling performance, we reveal a unique reaction mechanism. During the initial charge, an irreversible structural change occurs, removing all ammonium ions and inserting a small amount of Ca ions, forming Ca 0.37 V 7 O 16 . This suggests an ion-exchange reaction between calcium and ammonium ions. Subsequent cycles exhibit the reversible coinsertion and coextraction of calcium and ammonium ions. We observe that V 7 O 16 lacks structural stability without interlayer cations. Our findings offer insight into electrochemical reaction processes in crystal-water-free layered materials containing interlayer ammonium ions, highlighting the importance of cointercalation between ammonium and carrier ions for reversible cycling.

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Electrode materials for calcium batteries: Future directions and perspectives

Masese,

Kanyolo

2024

EcoEnergy

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Despite the prevailing dominance of lithium‐ion batteries in consumer electronics and electric vehicle markets, the growing apprehension over lithium availability has ignited a quest for alternative high‐energy‐density electrochemical energy storage systems. Rechargeable batteries featuring calcium (Ca) metal as negative electrodes (anodes) present compelling prospects, promising notable advantages in energy density, cost‐effectiveness, and safety. However, unlocking the full potential of rechargeable Ca metal batteries particularly hinges upon the strategic identification or design of high‐energy‐density positive electrode (cathode) materials. This imperative task demands expeditious synthetic routes tailored for their meticulous design. In this Perspective, we mainly highlight the development in the cathode materials for calcium batteries and accentuate the unparalleled promise of solid‐state metathesis routes in designing a diverse array of high‐performance electrode materials.

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Intercalation-type positive electrode materials for nonaqueous calcium-ion batteries

Cited by 5 publications

References 144 publications

Impact of Differential Ca²⁺ Coordination in Borohydride-Based Electrolyte Blends on Calcium Electrochemistry and SEI Formation

Impact of Differential Ca²⁺ Coordination in Borohydride-Based Electrolyte Blends on Calcium Electrochemistry and SEI Formation

(NH₄)₂V₇O₁₆ as a Cathode Material for Rechargeable Calcium-Ion Batteries: Structural Transformation and Co-Intercalation of Ammonium and Calcium Ions

Electrode materials for calcium batteries: Future directions and perspectives

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Intercalation-type positive electrode materials for nonaqueous calcium-ion batteries

Cited by 5 publications

References 144 publications

Impact of Differential Ca2+ Coordination in Borohydride-Based Electrolyte Blends on Calcium Electrochemistry and SEI Formation

Impact of Differential Ca2+ Coordination in Borohydride-Based Electrolyte Blends on Calcium Electrochemistry and SEI Formation

(NH4)2V7O16 as a Cathode Material for Rechargeable Calcium-Ion Batteries: Structural Transformation and Co-Intercalation of Ammonium and Calcium Ions

Electrode materials for calcium batteries: Future directions and perspectives

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Impact of Differential Ca²⁺ Coordination in Borohydride-Based Electrolyte Blends on Calcium Electrochemistry and SEI Formation

Impact of Differential Ca²⁺ Coordination in Borohydride-Based Electrolyte Blends on Calcium Electrochemistry and SEI Formation

(NH₄)₂V₇O₁₆ as a Cathode Material for Rechargeable Calcium-Ion Batteries: Structural Transformation and Co-Intercalation of Ammonium and Calcium Ions