Fast Intercalation in Locally Ordered Carbon Nanocrystallites for Superior Potassium Ions Storage

Han, Xu; Chen, YangQuan; Zhang, Panpan; Pan, Yang; Zhao, Yanhua; Meng, Shujuan; Wu, Jiansheng; Weng, Jian; Li, Sheng; Huo, Fengwei

doi:10.1002/adfm.202109672

Cited by 25 publications

(21 citation statements)

References 50 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In addition to defects caused by heteroatom doping and surface groups, NCC itself has many inherent defects. [ 26,93 ] Yu et al. [ 23 ] designed ultrathin 2D nanosheets into 3D mesoporous carbon nanosheets by the MgO template method (Figure 7e), which have a hierarchical pore structure and expanded interlayer spacing.…”

Section: Current Interpretations Of Storage Mechanismmentioning

confidence: 99%

“…In addition to defects caused by heteroatom doping and surface groups, NCC itself has many inherent defects. [26,93] Yu et al [23] designed ultrathin 2D nanosheets into 3D mesoporous carbon nanosheets by the MgO template method (Figure 7e), which have a hierarchical pore structure and expanded interlayer spacing. These morphological engineering can expose more active surfaces to the electrolyte and shorten the diffusion length of ions and electrons, thereby increasing the storage rate of sodium ions.…”

Section: Adsorptionmentioning

confidence: 99%

See 1 more Smart Citation

Noncrystalline Carbon Anodes for Advanced Sodium‐Ion Storage

et al. 2023

Self Cite

View full text Add to dashboard Cite

and have similar physical and chemical properties. [3][4][5] In addition, as sodium is the fourth most abundant element on earth, the preparation cost of SIBs is significantly lower than that of LIBs, which are expected to replace the latter in largescale energy storage power stations in response to the rapid consumption of lithium resources. However, due to the larger ionic radius of Na + (1.02 Å) than Li + (0.76 Å), lower electronegativity (0.93) than Li (0.98), and standard reduction potential (Na/Na + −2.71 V vs SHE) than Li (Li/Li + −3.04 V vs SHE), SIB electrodes face the challenges including slow electrochemical storage kinetics in solid-state, severe volume expansion, and low energy density. [6,7] It is well known that the electrode material is the core component that determines the performance of the battery. Thus, developing electrodes with excellent rate performance, extended cycle stability, high coulomb efficiency, and high specific capacity is one of the emphases in the study of SIBs. [8][9][10][11] As one of the most commonly used anodes for SIBs, carbonbased materials have great research significance because of their low cost, chemical stability, large surface area, and availability. [12][13][14] Since carbon is usually obtained by the thermal treatment of precursors (polymers, biomaterials, etc.), the carbonization temperature will affect their microstructure. During the heat treatment process, the types and number of carbon bonds (sp, sp 2 , and sp 3 ) will be changed and rearranged, and various carbon materials with different microstructures can be created [15,16] (Figure 1): amorphous carbon, nongraphitized carbon, and graphitic carbon. When the temperature exceeds 700 °C, the carbon bonds are simultaneously mixed in amorphous carbon with sp 2 , sp 3 , and sp hybridizations. [17] While the temperature further rises above 1200 °C, sp 2 -dominated amorphous carbon forms. This rich sp 2 -bonded carbon material comprises a stack of small graphitic nanocrystallites, forming a "turbostratic" structure. The random distribution of turbine domains and the distortion of carbon nanocrystals may create many micropores. Compared with the periodic and ordered atomic arrangement of crystalline materials, the atoms or nanodomains from amorphous carbon [18] and nongraphitized [19] carbon do not show long-range periodic order. Many properties of these two kinds of materials are pretty similar; thus, in this review, we collectively refer to these two as noncrystalline carbon (NCC).Developing an anode with excellent rate performance, long-cycle stability, high coulombic efficiency, and high specific capacity is one of the key research directions of sodium-ion batteries. Among all the anode materials, noncrystalline carbon (NCC) has great possibilities according to its supreme performance and low cost, but with the complexity and variability of the structure. With the in-depth study of the sodium storage behaviors of NCC in recent years, three modes of interlayer intercalation, clustering into micropores, and adso...

show abstract

Section: Current Interpretations Of Storage Mechanismmentioning

confidence: 99%

Section: Adsorptionmentioning

confidence: 99%

Noncrystalline Carbon Anodes for Advanced Sodium‐Ion Storage

et al. 2023

Self Cite

View full text Add to dashboard Cite

show abstract

“…16,17 Compared to graphite, hard carbon exhibits excellent rate capability and stability due to large interlayer spacing and high disorder. 18 However, the disadvantages are equally obvious and intolerable. A large number of pores and functional groups lead to extremely low initial Coulombic efficiency (ICE, even <40%) and low energy density, seriously hindering the application of hard carbons.…”

Section: Introductionmentioning

confidence: 99%

“…Although the most commonly used anode graphite for LIBs can form stable intercalation compounds with potassium, its theoretical capacity is only 279 mAh g –1 . , Worse, since the K + size is much larger than Li + (1.33–0.68 Å), the (de)intercalation leads to severe volumetric deformation, making the stability and rate capability of graphite very poor. , Compared to graphite, hard carbon exhibits excellent rate capability and stability due to large interlayer spacing and high disorder . However, the disadvantages are equally obvious and intolerable.…”

Section: Introductionmentioning

confidence: 99%

Integrated Design from Microstructural Engineering to Binder Optimization Enabling a Practical Carbon Anode with Ultrahigh ICE and Efficient Potassium Storage

Yan

Ren

Wang

et al. 2022

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

Potassium-ion batteries (PIBs) are emerging as a powerful alternative to lithium-ion battery systems in large-scale energy storage owing to plentiful resources. Nevertheless, pursuing high-yield anode materials with high initial Coulombic efficiency (ICE) and superior rate capability is still one of the most critical challenges in practical application. Herein, an integrated electrode (PC-x) derived from a petroleum coke precursor (carbon residue rate as high as 89%) is regulated from microstructural engineering to binder optimization devoting to high ICE and efficient potassium storage. Excitingly, with a strong assist from a sodium carboxymethyl cellulose (CMC) binder, the PC-900 anode displays an ultrahigh ICE of 80.5%, one of the highest values reported for PIB carbon anodes. Simultaneously, the PC-900 anode submits a high capacity (304.3 mAh g–1), superb rate (138.2 mAh g–1 at 10C), and excellent stability. Furthermore, the full cell exhibits an outstanding rate and cycling performance (210.7 mAh g–1 at 0.5C), confirming its large-scale application prospects. The ultrahigh ICE and excellent performance are mainly attributable to the beneficial microstructures (low surface area, functional group content, and larger interlayer spacing) created by microstructural engineering. Meanwhile, binder optimization also plays a crucial role in reducing the irreversible capacity and interface impedance, further improving the ICE and rate capability. Importantly, mechanism analysis confirms two-stage K+ storage behavior: reversible adsorption at edges and defects (>0.25 V) and intercalation into crystalline layers (<0.25 V). This work provides an efficient and easily scalable electrode design strategy for future practical applications of PIBs.

show abstract

“…[3b,4a,5] Identifying a superior carbon anode to commercial graphite for K + storage is the major challenge in developing high-energy and high-power PIBs.Two approaches to solving this problem have been developed: modifying the microstructure of graphite and developing other non-graphitic carbons as anodes. For the former, strategies such as increasing the interlayer spacing, [6] modifying morphology, [7] and disordering graphitic crystallites [8] have been explored to facilitate K + diffusion and precisely tune the void space to buffer the expansion of electrodes. These modified graphitic anodes generally exhibit high slope capacity due to additional defects or surfaces introduced for K + adsorption, excellent rate performance, and cycle stability.…”

mentioning

confidence: 99%

Discrete Graphitic Crystallites Promise High‐rate Ion Intercalation for KC₈ Formation in Potassium Ion Batteries

Zhang

Chen

et al. 2022

Advanced Energy Materials

View full text Add to dashboard Cite

conversion efficiency, and simple maintenance. [1] However, the rapid consumption and uneven distribution of lithium sources prevent it from being the only means of energy storage. [2] Potassium ion batteries (PIBs) have attracted tremendous attention as a complement to LIBs due to the higher abundance of the metal (K with 1.5 wt.% of the Earth's crust compared to 0.0017 wt.% for Li) and the higher ionic conductivity of K + in the electrolyte and their higher cell voltage than LIBs. [3] Most importantly, efficient intercalation of K + in graphite makes PIBs potentially match with the well-established graphite anode for LIBs. Graphite delivers a satisfactory theoretical capacity (279 mAh g −1 ) for K + by forming the stage-one intercalation compound (GIC) KC 8 at low potential, which gives a high energy density at the full-cell level. [4] However, compared with the small Li + (0.76 Å), the larger K + (1.38 Å) always has lower mobility in graphite resulting in a poor rate performance and a low capacity for PIBs, and leads to serious structural damage during K + intercalation/deintercalation and thus poor capacity retention. [3b,4a,5] Identifying a superior carbon anode to commercial graphite for K + storage is the major challenge in developing high-energy and high-power PIBs.Two approaches to solving this problem have been developed: modifying the microstructure of graphite and developing other non-graphitic carbons as anodes. For the former, strategies such as increasing the interlayer spacing, [6] modifying morphology, [7] and disordering graphitic crystallites [8] have been explored to facilitate K + diffusion and precisely tune the void space to buffer the expansion of electrodes. These modified graphitic anodes generally exhibit high slope capacity due to additional defects or surfaces introduced for K + adsorption, excellent rate performance, and cycle stability. However, their material densities and low-potential plateau capacity need to be enhanced. Nongraphitic carbons, both soft and hard, have been extensively explored as high-performance anodes for PIBs. [9] They usually deliver a remarkable rate performance due to their disordered structures with abundant edges for fast K + diffusion. They also have a large capacity and a long cycling life due to their large d 002 (interlayer spacing) and enough porosity for K + storage, and to accommodate the expansion. However, their low densities and high operating potential reduce both the gravimetric and volumetric energy densities at the full-cell level. Therefore, it remains a challenge to improve the power characteristics and Graphite has paved the way for commercial lithium-ion batteries and shows great potential as an anode for high-energy potassium-ion batteries (PIBs) due to its low-potential charge/discharge plateau. However, the restricted diffusion of large K + in graphite causes difficulties in generating the stageone graphite-intercalation compound (GIC) KC 8 at high rates and results in a low plateau capacity and an inferior rate performance. It i...

show abstract

Fast Intercalation in Locally Ordered Carbon Nanocrystallites for Superior Potassium Ions Storage

Cited by 25 publications

References 50 publications

Noncrystalline Carbon Anodes for Advanced Sodium‐Ion Storage

Noncrystalline Carbon Anodes for Advanced Sodium‐Ion Storage

Integrated Design from Microstructural Engineering to Binder Optimization Enabling a Practical Carbon Anode with Ultrahigh ICE and Efficient Potassium Storage

Discrete Graphitic Crystallites Promise High‐rate Ion Intercalation for KC₈ Formation in Potassium Ion Batteries

Contact Info

Product

Resources

About

Fast Intercalation in Locally Ordered Carbon Nanocrystallites for Superior Potassium Ions Storage

Cited by 25 publications

References 50 publications

Noncrystalline Carbon Anodes for Advanced Sodium‐Ion Storage

Noncrystalline Carbon Anodes for Advanced Sodium‐Ion Storage

Integrated Design from Microstructural Engineering to Binder Optimization Enabling a Practical Carbon Anode with Ultrahigh ICE and Efficient Potassium Storage

Discrete Graphitic Crystallites Promise High‐rate Ion Intercalation for KC8 Formation in Potassium Ion Batteries

Contact Info

Product

Resources

About

Discrete Graphitic Crystallites Promise High‐rate Ion Intercalation for KC₈ Formation in Potassium Ion Batteries