P-Doped Cotton Stalk Carbon for High-Performance Lithium-Ion Batteries and Lithium–Sulfur Batteries

Wei, Yanbin; Cheng, Wei; Huang, Yudai; Liu, Zhenjie; Sheng, Rui; Wang, Xingchao; Jia, Dianzeng; Tang, Xincun

doi:10.1021/acs.langmuir.2c01336

Cited by 11 publications

(12 citation statements)

References 46 publications

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“…This further suggests NPC-CZ has the shortest pathways for enhanced ion diffusion and electron transport efficiency for ions. 21 The fitted value of R ct for NC, NPC-Z, and NPC-CZ material was determined as 0.36, 0.24, and 0.23 Ω, respectively, implying the fastest charge transfer rates and the strongest transmission capacities in NPC-CZ. 56 The steep line observed in the low-frequency region indicates that NPC-CZ exhibits minimal Warburg impedance (W) due to its most extensive surface area, volume of pores, and least degree of graphitization, 57 ensuring rapid ion diffusion/charge transfer abilities and shortening ion transfer routes, ultimately leading to optimal capacitive behavior.…”

Section: Resultsmentioning

confidence: 96%

“…Cotton stalk-derived P-doped carbon materials (HPCSCMs) utilized inexpensive and abundant biological waste cotton stalks, which exhibited an impressive surface area (3463.14 m 2 g –1 ) along with hierarchical pores. As an anode for lithium-ion batteries, the sample reveals 1100 mAh g –1 at 0.1 A g –1 after 100 cycles, and the capacity is barely reduced after 1000 cycles …”

Section: Introductionmentioning

confidence: 99%

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Nitrogen-Doped Hierarchical Nanoporous Carbon Materials from Discarded Polyurethane Sponges via One-Step Double-Activation Method for Double-Layer Capacitors

Ma,

Liu,

Huan

et al. 2024

ACS Appl. Nano Mater.

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The self-induced N-doped micropore and mesopore hierarchical nanoporous carbon (NPC-CZ) was synthesized from a discarded shock-proof polyurethane sponge by using a onestep physical/chemical double-activation method with the introduction of ZnCl 2 and CO 2 . ZnCl 2 activation generated numerous micropores and mesopores, while subsequent CO 2 treatment further enhanced the microporosity and pore volume of NPC-CZ. Besides, the carbonation process formed oxygencontaining functional groups and converted the self-contained abundant amino groups in a shock-proof polyurethane sponge to N atom doping, which generated additional active sites and improved the surface wettability ability. NPC-CZ has a high specific surface area of 1108.9 m 2 g −1 and an abundant hierarchical nanoporous structure. The specific capacitances of NPC-CZ were found to reach 211.7 F g −1 at a current density of 0.5 A g −1 in a 2 M KOH electrolyte solution, while operating within a potential window of −1 to 0 V. Additionally, the excellent cycle stabilization of NPC-CZ was demonstrated by an impressive capacitance retention of 84.2% after undergoing 20000 cycles at a higher current density of 5 A g −1 . Furthermore, when employed as electrode materials in symmetric supercapacitors, NPC-CZ achieved a power density of 600 W kg −1 while maintaining an energy density of 6.33 Wh kg −1 . This research offers innovative perspectives on the transformation of discarded polyurethane sponges into highly potential nanostructured materials for capacitor electrodes.

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Section: Resultsmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Nitrogen-Doped Hierarchical Nanoporous Carbon Materials from Discarded Polyurethane Sponges via One-Step Double-Activation Method for Double-Layer Capacitors

Ma,

Liu,

Huan

et al. 2024

ACS Appl. Nano Mater.

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“…34 For the XRD pattern of NSPC@SiO 2 , no evident changes are observed after P doping. The Raman spectra of NSC@SiO 2 and NSPC@SiO 2 both exhibit a G band peak (1583.7 cm −1 ) and a D band peak (1333.6 cm −1 ), which are related to ordered graphitic carbon and carbon defects, respectively 35,36 (Figure 1b). The G and D intensity ratios (I G /I D ) of NSC@SiO 2 and NSPC@SiO 2 are 0.75 and 0.69, respectively, indicating that the carbon defects in NSPC@SiO 2 increase with P doping, which is favorable for enhancing the reaction kinetics and catalytic activity.…”

Section: Resultsmentioning

confidence: 99%

Regeneration of Activated Sludge into SiO₂-Decorated Heteroatom-Doped Porous Carbon as Advanced Electrodes for Li–S Batteries

Yang

Jia

Sun

et al. 2023

ACS Appl. Mater. Interfaces

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The regeneration of harmful activated sludge into an energy source is an important strategy for municipal sludge treatment and recycling. Herein, SiO2-modified N,S auto-doped porous carbon (NSC@SiO2) with high conductivity (70 S m–1) is successfully obtained through a simple calcination method of the activated sludge from wastewater treatment. Further, P-doped NSC@SiO2 (NSPC@SiO2) is designed to achieve a higher surface area (891 m2 g–1 vs 624 m2 g–1), a larger pore volume (0.87 cm3 g–1 vs 0.08 cm3 g–1), and more carbon defects. Due to its special structure, NSPC@SiO2 is used as a sulfur host of lithium–sulfur batteries. The results of polysulfide adsorption experiments, S 2p X-ray photoelectron spectra (XPS), Li2S nucleation experiments, polysulfide symmetric cells, measurement of the galvanostatic intermittent titration (GITT), polarization voltage difference, lithium-ion diffusion rate, and Tafel slope verified that NSPC@SiO2 greatly improved the adsorption capacity of polysulfides, lowered the barrier to Li2S formation and the internal resistances of cells, and accelerated Li+ ion diffusion and the reaction kinetics of polysulfide conversion, resulting in the excellent performance of polysulfide capture and superior rate performance and cyclic stability. By comparing NSPC@SiO2 with NSC@SiO2, a higher initial capacity (1377 mAh g–1 vs 1150 mAh g–1 at 0.1C), better rate capacity (912 mAh g–1 vs 719 mAh g–1 at 2C), and low capacity decay (0.094% per cycle within 200 cycles) are obtained. Our work provides direction for the treatment, disposal, and resource utilization of activated sludge.

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“…For example, Shao et al prepared a LiVO 3 anode with the modest charge capacity of 326 and 71 mA h g –1 at 0.1 and 5 A g –1 , respectively, which is mainly caused by its sluggish reaction kinetics and low charge transfer . Fortunately, it is found that heterogeneous element doping could distinctly improve charge transfer and Li + diffusion, that is, to achieve rapid reaction kinetics. – Our previous work has shown that C-doped LiVO 3 nanoflakes (NFs) exhibited higher capacity and better rate performance than pure LiVO 3 owing to the enhanced reaction kinetics . Moreover, it is well-known that structural design and morphology control for the electrodes directly affect the reaction kinetics and thus determine its comprehensive electrochemical performance. – Nevertheless, an effective structure design strategy for LiVO 3 is still in the initial research stage and faces certain challenges because its components are not easy to accurately regulate.…”

Section: Introductionmentioning

confidence: 99%

C-Doped LiVO₃ Honeycombs Derived from the Biomass Template Strategy for Superior Lithium Storage

Shi,

Yang,

Zhang

et al. 2023

Langmuir

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LiVO 3 as a prospective anode for lithium-ion batteries has drawn considerable focus based on its superior ion transfer capability and relatively elevated specific capacity. Nevertheless, the inherent low electrical conductivity and sluggish reaction kinetics hindered its commercial application. Herein, Cdoped LiVO 3 honeycombs (C-doped LiVO 3 HCs) are designed via introducing low-cost and scalable biomass carbon as a template, and the influence of the structure on the lithium storage property is systematically studied. The prepared C-doped LiVO 3 HC electrode delivers a high reversible capacity of 743.7 mA h g −1 at 0.5 A g −1 after 400 cycles and superior high-rate performance with an average discharge capacity of 420.8 mA h g −1 even at 5.0 A g −1 . The remarkable comprehensive electrochemical performance is attributed to the high electrical conductivity caused by carbon doping and rapid ion transport triggered by the honeycomb structure. This work may offer a rational design on both the hierarchical structure and doping engineering of future battery electrodes.

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P-Doped Cotton Stalk Carbon for High-Performance Lithium-Ion Batteries and Lithium–Sulfur Batteries

Cited by 11 publications

References 46 publications

Nitrogen-Doped Hierarchical Nanoporous Carbon Materials from Discarded Polyurethane Sponges via One-Step Double-Activation Method for Double-Layer Capacitors

Nitrogen-Doped Hierarchical Nanoporous Carbon Materials from Discarded Polyurethane Sponges via One-Step Double-Activation Method for Double-Layer Capacitors

Regeneration of Activated Sludge into SiO₂-Decorated Heteroatom-Doped Porous Carbon as Advanced Electrodes for Li–S Batteries

C-Doped LiVO₃ Honeycombs Derived from the Biomass Template Strategy for Superior Lithium Storage

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P-Doped Cotton Stalk Carbon for High-Performance Lithium-Ion Batteries and Lithium–Sulfur Batteries

Cited by 11 publications

References 46 publications

Nitrogen-Doped Hierarchical Nanoporous Carbon Materials from Discarded Polyurethane Sponges via One-Step Double-Activation Method for Double-Layer Capacitors

Nitrogen-Doped Hierarchical Nanoporous Carbon Materials from Discarded Polyurethane Sponges via One-Step Double-Activation Method for Double-Layer Capacitors

Regeneration of Activated Sludge into SiO2-Decorated Heteroatom-Doped Porous Carbon as Advanced Electrodes for Li–S Batteries

C-Doped LiVO3 Honeycombs Derived from the Biomass Template Strategy for Superior Lithium Storage

Contact Info

Product

Resources

About

Regeneration of Activated Sludge into SiO₂-Decorated Heteroatom-Doped Porous Carbon as Advanced Electrodes for Li–S Batteries

C-Doped LiVO₃ Honeycombs Derived from the Biomass Template Strategy for Superior Lithium Storage