Development of P3-K<sub>0.69</sub>CrO<sub>2</sub> as an ultra-high-performance cathode material for K-ion batteries

Hwang, Jang Yeon; Kim, Jongsoon; Yu, Tae Yeon; Myung, Seung‐Taek; Sun, Yang Kook

doi:10.1039/c8ee01365a

Cited by 161 publications

(134 citation statements)

References 33 publications

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“…It is evident that few high‐voltage cathodes exist (exhibiting average working voltages of close to or beyond 4 V); Prussian organic moieties and polyanionic compounds such as KVOPO 4 , KVP 2 O 7 , KVPO 4 F, amongst others dominating as high‐voltage cathode candidates. Potassium‐based oxides tend to show low average voltage; however, this prevailing notion was recently obliterated by the design of tellurium‐doped K 2/3 Ni 2/3 Te 1/3 O 2 (or equivalently as K 2 Ni 2 TeO 6 , for simplicity) and K 2/3 Ni 1/3 Co 1/3 Te 1/3 O 2 (K 2 NiCoTeO 6 ) as high‐voltage layered cathode materials (Figure a) . Despite the alluring prospects of using these high‐voltage cathode materials to develop a high‐voltage battery system, instability of organic electrolytes at high‐voltage operation coupled with the high reactivity of potassium metal anode continues to cast doubt on the safety of electrolytes based on organic solvents …”

Section: Introductionmentioning

confidence: 99%

Sulfonylamide‐Based Ionic Liquids for High‐Voltage Potassium‐Ion Batteries with Honeycomb Layered Cathode Oxides

et al. 2019

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The world is at the cusp of a new era where pivotal importance is being attached to the development of sustainable and high‐performance energy storage systems. Potassium‐ion batteries are deemed not only cheap battery candidates, but also as the penultimate high‐voltage energy storage systems within monovalent‐cation chemistries. However, their performance and sustainability are undermined by the lack of suitable electrolytes for high‐voltage operation, particularly owing to the limited availability of cathode materials. Here, the potential of ionic liquids based on potassium bis(trifluoromethanesulfonyl)amide (KTFSA) as high‐voltage electrolytes is presented by assessing their physicochemical properties along with the electrochemical properties upon coupling with new high‐voltage layered cathode materials. These ionic liquids demonstrate a wide electrochemical window (around 6.0 V), making them feasible and safe electrolytes for the high‐voltage potassium‐ion battery configuration. This is proven by matching this electrolyte with new high‐voltage layered cathode compositions, demonstrating stable electrochemical performance. The present findings of electrochemically stable ionic liquids based on potassium bis(trifluoromethanesulfonyl)amide will bolster further advancement of high‐performance cathode materials, whose performance at high‐voltage regimes were apparently restricted by the paucity of suitable and compatible electrolytes.

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Section: Introductionmentioning

confidence: 99%

Sulfonylamide‐Based Ionic Liquids for High‐Voltage Potassium‐Ion Batteries with Honeycomb Layered Cathode Oxides

et al. 2019

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“…Current growth rates in lithiumion battery (LIB) manufacturing are not sustainable given our limited lithium resources. [8][9][10][11][12][13][14] Among these, manganese layered oxides are particularly promising due to the high natural abundance and nontoxicity of manganese. [1] Of these, PIBs are more promising due to the closeness of the K + /K redox potential (−2.9 V vs H + /H 2 O) to that of Li + /Li (−3.0 V vs H + /H 2 O), as compared to Na + /Na (−2.7 V vs H + /H 2 O), and the consequential ease of reversible K + intercalation into the most common LIB negative electrode, graphite.…”

mentioning

confidence: 99%

Structural Insight into Layer Gliding and Lattice Distortion in Layered Manganese Oxide Electrodes for Potassium‐Ion Batteries

Zhang

Didier

Pang

et al. 2019

Advanced Energy Materials

130

117

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grids. Current growth rates in lithiumion battery (LIB) manufacturing are not sustainable given our limited lithium resources. In this context, alternative battery systems with low cost are sought, with sodium-and potassium-ion batteries (SIBs and PIBs, respectively) regarded as suitable replacements due to the high natural abundance of sodium and potassium and their similar working mechanism to LIBs. [1] Of these, PIBs are more promising due to the closeness of the K + /K redox potential (−2.9 V vs H + /H 2 O) to that of Li + /Li (−3.0 V vs H + /H 2 O), as compared to Na + /Na (−2.7 V vs H + /H 2 O), and the consequential ease of reversible K + intercalation into the most common LIB negative electrode, graphite. [2][3][4] The slow kinetics of the reversible insertion of K + in electrode materials as a result of its relatively large ionic radius of 1.38 Å is a major issue for the realization of high-performance PIBs. [5][6][7] For PIB technology to be successful, scientists need to find stable electrode materials capable of reversibly hosting K + relatively quickly. Transition metal layered oxides possess a 2D structure that can accommodate large ions and are attracting interest as potential PIB electrode materials. [8][9][10][11][12][13][14] Among these, manganese layered oxides are particularly promising due to the high natural abundance and nontoxicity of manganese. A range of layered K x MnO 2 structure types can be prepared [15,16] including Potassium-ion batteries (PIBs) are an emerging, affordable, and environmentally friendly alternative to lithium-ion batteries, with their further development driven by the need for suitably performing electrode materials capable of reversibly accommodating the relatively large K + . Layer-structured manganese oxides are attractive as electrodes for PIBs, but suffer from structural instability and sluggish kinetics of K + insertion/extraction, leading to poor rate capability. Herein, cobalt is successfully introduced at the manganese site in the K x MnO 2 layered oxide electrode material and it is shown that with only 5% Co, the reversible capacity increases by 30% at 22 mA g -1 and by 92% at 440 mA g -1 . In operando synchrotron X-ray diffraction reveals that Co suppresses Jahn-Teller distortion, leading to more isotropic migration pathways for K + in the interlayer, thus enhancing the ionic diffusion and consequently, rate capability. The detailed analysis reveals that additional phase transitions and larger volume change occur in the Co-doped material as a result of layer gliding, with these associated with faster capacity decay, despite the overall capacity remaining higher than the pristine material, even after 500 cycles. These results assert the importance of understanding the detailed structural evolution that underpins performance that will inform the strategic design of electrode materials for high-performance PIBs.

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“…The designing of high‐voltage KIBs are considered to be a challenge due to the limited availability of high‐voltage cathodes and high‐voltage stable electrolytes. In recent years, some cathode materials (K 2/3 Ni 2/3 Te 1/3 O 2 , K 2/3 Ni 1/3 Co 1/3 Te 1/3 O 2 ) have been explored in this aspect . Hence the main challenge is to develop electrolyte which can withstand at high voltages.…”

Section: Different Electrolytesmentioning

confidence: 99%

Advancements and Challenges in Potassium Ion Batteries: A Comprehensive Review

Rajagopalan

Tang

et al. 2020

Adv Funct Materials

610

389

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Demand for energy in day to day life is increasing exponentially. However, existing energy storage technologies like lithium ion batteries cannot stand alone to fulfill future needs. In this regard, potassium ion batteries (KIBs) that utilize K ions in their charge storage mechanism have attracted considerable attention due to their unique properties and are therefore established as one of the future battery systems of interest among the scientific community. Nevertheless, the development and identification of appropriate electrode materials is very essential for practical applications. This review features the current development in KIBs electrode and electrolyte materials, the present challenges facing this technology (in the commercial aspect), and future aspects to develop fully functional KIBs. The potassium storage mechanisms, evolution of the KIBs, and the advantages and disadvantages of each category of materials are included. Additionally, various approaches to enhance the electrochemical performances of KIBs are also discussed. This review is not only an amalgamation of different viewpoints in literature, but also contains concise perspectives and strategies. Moreover, the potential emergence of a novel class of K‐based dual ion batteries is also analyzed for the first time.

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Development of P3-K_0.69CrO₂ as an ultra-high-performance cathode material for K-ion batteries

Cited by 161 publications

References 33 publications

Sulfonylamide‐Based Ionic Liquids for High‐Voltage Potassium‐Ion Batteries with Honeycomb Layered Cathode Oxides

Sulfonylamide‐Based Ionic Liquids for High‐Voltage Potassium‐Ion Batteries with Honeycomb Layered Cathode Oxides

Structural Insight into Layer Gliding and Lattice Distortion in Layered Manganese Oxide Electrodes for Potassium‐Ion Batteries

Advancements and Challenges in Potassium Ion Batteries: A Comprehensive Review

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Development of P3-K0.69CrO2 as an ultra-high-performance cathode material for K-ion batteries

Cited by 161 publications

References 33 publications

Sulfonylamide‐Based Ionic Liquids for High‐Voltage Potassium‐Ion Batteries with Honeycomb Layered Cathode Oxides

Sulfonylamide‐Based Ionic Liquids for High‐Voltage Potassium‐Ion Batteries with Honeycomb Layered Cathode Oxides

Structural Insight into Layer Gliding and Lattice Distortion in Layered Manganese Oxide Electrodes for Potassium‐Ion Batteries

Advancements and Challenges in Potassium Ion Batteries: A Comprehensive Review

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Development of P3-K_0.69CrO₂ as an ultra-high-performance cathode material for K-ion batteries