A new energy storage system: Rechargeable potassium-selenium battery

Tai, Zhixin; Zhang, Qing; Wang, Hongqiang; Pang, Wei Kong; Liu, Huan; Konstantinov, Konstantin; Guo, Zaiping

doi:10.1016/j.nanoen.2017.03.029

Cited by 176 publications

(164 citation statements)

References 38 publications

(40 reference statements)

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“…As for the cycling stability, the N‐CNS performs the best reversible capacity and capacity retention among all anodes investigated here (Figure c), confirming the importance of pyridinic‐N/pyrrolic‐N‐doping in carbon as anode for PIBs . The rate capability of our N‐CNS anode also exceeds all other carbon‐based anode materials for PIBs (Figure d) . Compared with other carbon‐based electrodes reported for PIBs in the literature (Table S2, Supporting Information), the N‐CNS delivers unprecedented long cycle performance (321 mAh g −1 at 5 A g −1 after 5000 cycles), superior rate performance (145 mAh g −1 at 20 A g −1 after 5000 cycles), and high Coulombic efficiency (≈100%) (Figure e and Figure S11, Supporting Information) .…”

supporting

confidence: 70%

Sodium/Potassium‐Ion Batteries: Boosting the Rate Capability and Cycle Life by Combining Morphology, Defect and Structure Engineering

et al. 2020

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Carbon‐based materials have been considered as the most promising anode materials for both sodium‐ion batteries (SIBs) and potassium‐ion batteries (PIBs), owing to their good chemical stability, high electrical conductivity, and environmental benignity. However, due to the large sizes of sodium and potassium ions, it is a great challenge to realize a carbon anode with high reversible capacity, long cycle life, and high rate capability. Herein, by rational design, N‐doped 3D mesoporous carbon nanosheets (N‐CNS) are successfully synthesized, which can realize unprecedented electrochemical performance for both SIBs and PIBs. The N‐CNS possess an ultrathin nanosheet structure with hierarchical pores, ultrahigh level of pyridinic N/pyrrolic N, and an expanded interlayer distance. The beneficial features that can enhance the Na‐/K‐ion intercalation/deintercalation kinetic process, shorten the diffusion length for both ions and electrons, and accommodate the volume change are demonstrated. Hence, the N‐CNS‐based electrode delivers a high capacity of 239 mAh g−1 at 5 A g−1 after 10 000 cycles for SIBs and 321 mAh g−1 at 5 A g−1 after 5000 cycles for PIBs. First‐principles calculation shows that the ultrahigh doping level of pyridinic N/pyrrolic N contributes to the enhanced sodium and potassium storage performance by modulating the charge density distribution on the carbon surface.

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confidence: 70%

Sodium/Potassium‐Ion Batteries: Boosting the Rate Capability and Cycle Life by Combining Morphology, Defect and Structure Engineering

et al. 2020

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“…Consequently, novel battery systems such as sodium-ion batteries (SIBs), [3] aluminum-ion batteries (AIBs), [4] and dual-ion batteries (DIBs) [5][6][7][8][9][10][11] characterized by higher abundance and lower cost have attracted extensive attentions. [12][13][14][15][16][17] Compared anode based on the KPF 6 containing organic electrolyte. [12][13][14][15][16][17] Compared anode based on the KPF 6 containing organic electrolyte.…”

Section: Dual-ion Batteriesmentioning

confidence: 99%

“…Apparently, the dual-graphite DIBs show advantages in terms of low cost, good safety, and environmental friendliness. [12][13][14][15][16][17] Compared Extensive researches on DIBs have been focused on exploiting high-capacity cathode materials, [6c] alternative anode materials, [6a,7-11] as well as suitable electrolyte compositions, [5] and great progresses on their development have been made.…”

mentioning

confidence: 99%

A Dual‐Carbon Battery Based on Potassium‐Ion Electrolyte

Zhang

et al. 2017

Advanced Energy Materials

258

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with SIBs, potassium-ion batteries (KIBs) deliver a higher working voltage due to the lower redox potential of K + /K (−2.92 V vs SHE) than that of Na + /Na (−2.71 V vs SHE). [14] In addition, K + has been demonstrated to be reversibly intercalated/ deintercalated into graphite anode, while very limited amounts of Na + could. [14] However, as the research on KIBs is still at the infancy stage, the mechanisms at an atomic scale and interfaces are unclear. In addition, owing to the large size of K + that would cause sluggish kinetics, only a few of cathode materials (Prussian blue and its analogues) [16] and anode materials (graphite, [14] Sn 4 P 3 /C) [13] were investigated. Therefore, developing suitable electrode materials with good performance as well as comprehensively investigating the mechanism are of great importance.On the other hand, another new type of battery called dual-ion battery (DIB) [5][6][7][8][9][10][11] also arouses scientists' concern, which generally consists of dual graphitic carbon electrodes. Owing to the intrinsic redox amphotericity of graphitic carbon materials, both cations (Li + ) and anions (PF 6 − , BF 4 − , TFSI − , etc.) are intercalated/deintercalated into graphite anode and graphite cathode, respectively, during the charging/discharging process in the dual-graphite DIB. Apparently, the dual-graphite DIBs show advantages in terms of low cost, good safety, and environmental friendliness. In addition, the high working voltage (mainly above 4.5 V) [5] of the DIB caused by high anion intercalation potential is also beneficial for high energy density. Extensive researches on DIBs have been focused on exploiting high-capacity cathode materials, [6c] alternative anode materials, [6a,7-11] as well as suitable electrolyte compositions, [5] and great progresses on their development have been made.In this work, on the purpose of combining both advantages of KIBs and DIBs, we first report a dual-carbon battery (DCB) based on a potassium-ion electrolyte (1 m KPF 6 in carbonate solvent), using expanded graphite (EG) as cathode material and mesocarbon microbead (MCMB) as anode. The working mechanism of the as-prepared K-ion-based dual-carbon battery (named as K-DCB) was investigated, which was further demonstrated to deliver a reversible discharge capacity of 61 mA h g −1 at 1 C (1 C corresponding to 100 mA g −1 ) current rate and also show good cycling performance for 100 cycles with negligible capacity decay. Moreover, the battery works reversibly and stably over a wide voltage window of 3.0-5.2 V with medium discharge voltage of 4.5 V, the highest value among the reported KIBs. [12][13][14][15][16] Figure 1a schematically shows the working mechanism of the K-DCB configuration utilizing an EG cathode and MCMB Although potassium-ion batteries (KIBs) have been considered to be promising alternatives to conventional lithium-ion batteries due to large abundance and low cost of potassium resources, their development still stays at the infancy stage due to the lack of appropriate cathode and anod...

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“…[25][26][27][28][29][30] However, the practical applications of RT NaS batteries are facing two major challenges: (i) sulfur has a low electronic conductivity (5 × 10 −30 S cm −1 at 25 °C), thus leading to sluggish electrochemical reaction processes and low utilization of the active sulfur in the electrode; (ii) severe "polysulfide shuttle effect," i.e., migration of dissolved polysulfide intermediate products through the porous separator between the cathode and the anode, which leads to rapid capacity fade during cycling. Selenium is a chemical analogue of S [32,33] and is considered to be an alternative electrode materials for SIBs due to its much higher electronic conductivity (1 × 10 −3 S m −1 ) as indicated in Figure S1 in the Supporting Information, volumetric capacity (3253 A h L −1 ) comparable to that of S (3467 A h L −1 ), and stable function in the relatively low-cost carbonate-based electrolytes. However, the intrinsic challenges of RT NaS batteries have been far from completely solved.…”

mentioning

confidence: 99%

Long Cycle Life, Low Self‐Discharge Sodium–Selenium Batteries with High Selenium Loading and Suppressed Polyselenide Shuttling

Wang

Jiang

Manthiram

2017

Advanced Energy Materials

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of sodium. [9,13] In addition, the electrode dynamics and thermodynamic knowledge accrued recently for LIBs could be employed to ensure rapid advances in SIBs. [14][15][16][17][18] Thus, development of viable room-temperature sodium-ion batteries is attracting increasing attention. [19][20][21][22][23][24] Recently, room-temperature (RT) sodium-sulfur (NaS) batteries, based on the conversion reaction chemistry, have triggered extensive research interest due to the high charge-storage capacity and the abundance of both sodium and sulfur. [25][26][27][28][29][30] However, the practical applications of RT NaS batteries are facing two major challenges: (i) sulfur has a low electronic conductivity (5 × 10 −30 S cm −1 at 25 °C), thus leading to sluggish electrochemical reaction processes and low utilization of the active sulfur in the electrode; (ii) severe "polysulfide shuttle effect," i.e., migration of dissolved polysulfide intermediate products through the porous separator between the cathode and the anode, which leads to rapid capacity fade during cycling. [31] Many approaches have been pursued to mitigate these issues, including employing modified separators, [30] porous carbon matrix, [26] etc. However, the intrinsic challenges of RT NaS batteries have been far from completely solved. Selenium is a chemical analogue of S [32,33] and is considered to be an alternative electrode materials for SIBs due to its much higher electronic conductivity (1 × 10 −3 S m −1 ) as indicated in Figure S1 in the Supporting Information, volumetric capacity (3253 A h L −1 ) comparable to that of S (3467 A h L −1 ), and stable function in the relatively low-cost carbonate-based electrolytes. [34][35][36] However, bulk Se particles still suffer from low active material utilization and Coulombic efficiency due to its electronically insulating properties and shuttling of high-order polyselenides. To circumvent these problems, the current efforts are mainly concentrated on improving the electrical conductivity and entrapping the active material within the cathode region, which include microporous/mesoporous carbon-selenium, [37][38][39] slit microporous carbon-selenium, [34] and flexible porous carbon nanofiberselenium. [40,41] With these approaches, the introduction of additional components (such as carbon black and binders) often lowers the energy density of NaSe batteries. Also, fabrication of these electrodes often involves complex multistep processes.In light of these pros and cons, we present herein a facile and scalable strategy to design carbon nanofiber (CNF)/selenium The use of selenium as a cathode in rechargeable sodium-selenium batteries is hampered by low Se loading, inferior electrode kinetics, and polyselenide shuttling between the cathode and anode. Here a high-performance sodiumselenium cell is presented by coupling a binder-free, self-interwoven carbon nanofiber-selenium cathode with a light-weight carbon-coated bifunctional separator. With this strategy, electrodes with a high Se mass loading (4.4 mg cm −2 ) rende...

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A new energy storage system: Rechargeable potassium-selenium battery

Cited by 176 publications

References 38 publications

Sodium/Potassium‐Ion Batteries: Boosting the Rate Capability and Cycle Life by Combining Morphology, Defect and Structure Engineering

Sodium/Potassium‐Ion Batteries: Boosting the Rate Capability and Cycle Life by Combining Morphology, Defect and Structure Engineering

A Dual‐Carbon Battery Based on Potassium‐Ion Electrolyte

Long Cycle Life, Low Self‐Discharge Sodium–Selenium Batteries with High Selenium Loading and Suppressed Polyselenide Shuttling

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