Nitrogen-rich fibrous carbon enabling polysulfide conversion for lithium–sulfur batteries

Hai Lin , Zhen Du , Lingyong Xu , Chengming Li , Yuepeng Guan , Yaqin Huang

Collagen and Leather ›› 2025, Vol. 7 ›› Issue (1)

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Collagen and Leather ›› 2025, Vol. 7 ›› Issue (1) DOI: 10.1186/s42825-025-00206-9
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Nitrogen-rich fibrous carbon enabling polysulfide conversion for lithium–sulfur batteries

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Abstract

The practical implementation of lithium–sulfur (Li–S) batteries is hindered by their poor rate performance and rapid capacity fade, primarily due to the sluggish kinetics of polysulfide conversion. To overcome these challenges, a nitrogen-rich fibrous carbon (NFC) material was synthesized using gelatin and g-C3N4 as raw materials through a stepwise pyrolysis process. The unique fibrous microstructure of NFC endows it with high ionic and electronic conductivities, facilitating rapid Li ion and electron transports. Furthermore, nitrogen doping increases the electrochemical performance of the Li–S battery by improving polysulfide adsorption and conversion kinetics. Consequently, the Li–S battery incorporated with NFC demonstrates significantly improved rate performance, exhibiting a high discharge specific capacity of 721 mAh g−1 at 4 C. Additionally, the pouch cell incorporating NFC displays a high average capacity of 821.6 mAh g−1 over 40 cycles at 0.1 C, with high cycling stability and a capacity retention rate exceeding 96%. These results highlight the effectiveness of NFC in improving the cycle longevity of Li–S batteries, thereby heralding a significant stride forward in their practical implementation in energy storage systems.

Keywords

Nitrogen-rich fibrous carbon / Gelatin / Biomass carbon / Lithium–sulfur battery / Electrochemistry

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Hai Lin, Zhen Du, Lingyong Xu, Chengming Li, Yuepeng Guan, Yaqin Huang. Nitrogen-rich fibrous carbon enabling polysulfide conversion for lithium–sulfur batteries. Collagen and Leather, 2025, 7(1): DOI:10.1186/s42825-025-00206-9

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

SongH, MünchK, LiuX, ShenK, ZhangR, WeintrautT, et al.. All-solid-state Li–S batteries with fast solid–solid sulfur reaction. Nature, 2025, 637(8047): 846-853.

[2]

ShenX, ZhangX-Q, DingF, HuangJ-Q, XuR, ChenX, YanC, SuF-Y, ChenC-M, LiuX, ZhangQ. Advanced electrode materials in lithium batteries: retrospect and prospect. Energy Mater Adv, 2021, 2021: 1-15.

[3]

LiuYT, EliasY, MengJS, AurbachD, ZouRQ, XiaDG, et al.. Electrolyte solutions design for lithium–sulfur batteries. Joule, 2021, 5(9): 2323-2364.

[4]

ZhangY, ZhangX, SilvaSRP, DingB, ZhangP, ShaoG. Lithium–sulfur batteries meet electrospinning: recent advances and the key parameters for high gravimetric and volume energy density. Adv Sci (Weinh), 2022, 94e2103879.

[5]

DengR, WangM, YuH, LuoS, LiJ, ChuF, et al.. Recent advances and applications toward emerging lithium–sulfur batteries: working principles and opportunities. Energy Environ Mater, 2022, 5(3): 777-799.

[6]

JiaY, WangZ, HanZ, LiJ, ZhangM, LaoZ, HanY, GaoR, GaoJ, ZhengZ, ChenA, LiH, MaoR, TaoK, LiJ, ZhouG. Variable and intelligent catalyst design based on local chemical environments in sulfur redox reactions. Joule, 2025, 95101878.

[7]

SongN, MaJ, LiangY, WangP, YuanJ, XiongS, et al.. Phase and orbital engineering effectuating efficient adsorption and catalysis toward high‐energy lithium−sulfur batteries. Adv Mater, 2025.

[8]

ShiM, HanX, QuW, JiangM, LiQ, JiangF, et al.. Nanocellulose‐derived hierarchical carbon framework‐supported P‐Doped MoO2 nanoparticles for optimizing redox kinetics in lithium–sulfur batteries. Adv Mater, 2025.

[9]

ZhangY, YuT, XiaoR, TangP, FangR, LiZ, ChengH-M, SunZ, LiF. The role of long‐range interactions between high‐entropy single‐atoms in catalyzing sulfur conversion reactions. Adv Mater, 2025.

[10]

WangR, WuR, DingC, ChenZ, XuH, LiuY, et al.. Porous carbon architecture assembled by cross-linked carbon leaves with implanted atomic cobalt for high-performance Li–S batteries. Nanomicro Lett, 2021, 131151.

[11]

YuZ, LiuM, GuoD, WangJ, ChenX, LiJ, et al.. Radially inwardly aligned hierarchical porous carbon for ultra-long-life lithium–sulfur batteries. Angew Chem Int Ed Engl, 2020, 59(16): 6406-6411.

[12]

ZhangL, WanF, WangX, CaoH, DaiX, NiuZ, et al.. Dual-functional graphene carbon as polysulfide trapper for high-performance lithium sulfur batteries. ACS Appl Mater Interfaces, 2018, 10(6): 5594-5602.

[13]

LiX, YuJ, LiW, LiaoY, LiM, ZhaoB, LiuX, HuangS, XiaS, ZhangJ, JiangY. Non-metal iodine single-atom catalysts anchored on N-doped graphene for high-performance lithium–sulfur battery. Chem Eng J, 2025, 505159355.

[14]

ChungSH, ManthiramA. High-performance Li–S batteries with an ultra-lightweight MWCNT-coated separator. J Phys Chem Lett, 2014, 5(11): 1978-1983.

[15]

QianM, TangY, LiuL, ZhangY, LiX, ChenJJ, FangC, LeiY, WangG. 1D hybrid consisting of LiTi2(PO4)3 with highly-active (113) crystal facets and carbon nanotubes: a bidirectional catalyst for advanced lithium–sulfur batteries. Chem Eng J, 2025, 505159727.

[16]

LuoY, LiuS, ChenM, HeY, ZhangW, YeY, ChenY, WangM, LuoY, LiuH, ShuH, YuR, WangX. Bimetallic synergistic catalysis strategy with one-dimensional CuCo–NC for enhanced wide-temperature stability in high-energy lithium–sulfur batteries. Chem Eng J, 2025, 505159158.

[17]

YamsangN, SittiwongJ, SrifaP, BoekfaB, SawangphrukM, MaihomT, LimtrakulJ. First-principle study of lithium polysulfide adsorption on heteroatom doped graphitic carbon nitride for lithium–sulfur batteries. Appl Surf Sci, 2021, 565150378.

[18]

WangJ, HanWQ. A review of heteroatom doped materials for advanced lithium–sulfur batteries. Adv Func Mater, 2021, 3222107166.

[19]

ZhangW, LiY, LvH, XieS, ZhuJ, XuJ, et al.. A comparison study of the electrocatalytic sulfur reduction activity on heteroatom-doped graphene for Li–S battery. Small Struct, 2023, 432200244.

[20]

GuoY, JinZ, LuJ, WeiL, WangW, HuangY, et al.. Engineering a deficient-coordinated single-atom indium electrocatalyst for fast redox conversion in practical 500 W h kg1-level pouch lithium–sulfur batteries. Energy Environ Sci, 2023, 16(11): 5274-5283.

[21]

WangQ, KimH, LiZ, SongL, YoonW-S, BulakheRN, KimJM. Propelling polysulfides conversion in lithium–sulfur batteries via separator modification with nitrogen-doped porous carbon nanosheets decorated by iron carbide nanoparticles. Chem Eng J, 2025, 507160588.

[22]

ZhangJ, ZhangQ, QuX, XuG, FanB, YanZ, et al.. Hierarchically pyridinic-nitrogen enriched porous carbon for advanced sodium-ion and lithium–sulfur batteries: electrochemical performance and in situ Raman spectroscopy investigations. Appl Surf Sci, 2022, 574151559.

[23]

ZhaoZ, YiZ, LiH, PathakR, ChengX, ZhouJ, et al.. Understanding the modulation effect and surface chemistry in a heteroatom incorporated graphene-like matrix toward high-rate lithium–sulfur batteries. Nanoscale, 2021, 13(35): 14777-14784.

[24]

YangX, YangD, ZhangG, ZuoH. Preparation of mesoporous carbon aerogels via ambient pressure drying using a self-sacrificing melamine-formaldehyde template. J Power Sourc, 2021, 482229135.

[25]

YangY, WangJ, ZuoP, QuS, ShenW. Layer-stacked graphite-like porous carbon for flexible all-solid-state supercapacitor. Chem Eng J, 2021, 425130609.

[26]

WangJ, TangJ, DingB, MalgrasV, ChangZ, HaoX, et al.. Hierarchical porous carbons with layer-by-layer motif architectures from confined soft-template self-assembly in layered materials. Nat Commun, 2017, 8115717.

[27]

VersaciD, CozzarinM, AmiciJ, FranciaC, LeivaEPM, VisintinA, BodoardoS. Influence of synthesis parameters on g-C3N4 polysulfides trapping: a systematic study. Appl Mater Today, 2021, 25101169.

[28]

MashhadimoslemH, JafariM, KhosrowshahiMS, GhaemiA, ElkamelA. Effective modified MWCNT super adsorbent for oxygen and nitrogen adsorption. Diam Relat Mater, 2023, 136109959.

[29]

LiuJ, ChuC, WeiL, FengJ, ShenJ. Iron/cobalt-decorated nitrogen-rich 3D layer-stacked porous biochar as high-performance oxygen reduction air-cathode catalyst in microbial fuel cell. Biosens Bioelectron, 2023, 222114926.

[30]

MaL, LiZB, LiJL, DaiY, QianC, ZhuYF, et al.. Phytic acid-induced nitrogen configuration adjustment of active nitrogen-rich carbon nanosheets for high-performance potassium-ion storage. J Mater Chem A, 2021, 9(45): 25445-25452.

[31]

WangJ, MengZ, YangW, YanX, GuoR, HanWQ. Facile synthesis of rGO/g-C(3)N(4)/CNT microspheres via an ethanol-assisted spray-drying method for high-performance lithium–sulfur batteries. ACS Appl Mater Interfaces, 2019, 11(1): 819-827.

[32]

HeW, HeX, DuM, BieS, LiuJ, WangY, et al.. Three-dimensional functionalized carbon nanotubes/graphitic carbon nitride hybrid composite as the sulfur host for high-performance lithium–sulfur batteries. J Phys Chem C, 2019, 123(26): 15924-15934.

[33]

DingY, ZengM, ZhengQ, ZhangJ, XuD, ChenW, et al.. Bidirectional and reversible tuning of the interlayer spacing of two-dimensional materials. Nat Commun, 2021, 1215886.

[34]

LiuJ, ZhangY, ZhangL, XieF, VasileffA, QiaoSZ. Graphitic carbon nitride (g-C(3)N(4))-derived N-rich graphene with tuneable interlayer distance as a high-rate anode for sodium-ion batteries. Adv Mater, 2019, 3124e1901261.

[35]

LiuG, TangZ, GuX, LiN, LvH, HuangY, et al.. Boosting photocatalytic nitrogen reduction to ammonia by dual defective -C N and K-doping sites on graphitic carbon nitride nanorod arrays. Appl Catal B, 2022, 317121752.

[36]

YuH, ShiR, ZhaoY, BianT, ZhaoY, ZhouC, et al.. Alkali-assisted synthesis of nitrogen deficient graphitic carbon nitride with tunable band structures for efficient visible-light-driven hydrogen evolution. Adv Mater, 2017, 29161605148.

[37]

WangX, XuJ, LiuJ, LiuJ, XiaF, WangC, et al.. Mechanism of Cr(VI) removal by magnetic greigite/biochar composites. Sci Total Environ, 2020, 700134414.

[38]

HoslettJ, GhazalH, KatsouE, JouharaH. The removal of tetracycline from water using biochar produced from agricultural discarded material. Sci Total Environ, 2021, 751141755.

[39]

KimJ, KimSJ, JungE, MokDH, PaidiVK, LeeJ, et al.. Atomic structure modification of Fe–N–C catalysts via morphology engineering of graphene for enhanced conversion kinetics of lithium–sulfur batteries. Adv Func Mater, 2022, 32192110857.

[40]

ZhangJ, ShiY, DingY, PengL, ZhangW, YuG. A Conductive molecular framework derived Li2S/N, p-codoped carbon cathode for advanced lithium–sulfur batteries. Adv Energy Mater, 2017, 7141602876.

[41]

ZhangLM, ZhaoWQ, YuanSH, JiangF, ChenXQ, YangY, et al.. Engineering the morphology/porosity of oxygen-doped carbon for sulfur host as lithium–sulfur batteries. J Energy Chem, 2021, 60: 531-545.

[42]

ChoiYJ, LeeG-W, KimYH, KimH-K, KimK-B. Microspherical assembly of selectively pyridinic N-doped nanoperforated graphene for stable Li-metal anodes: synergistic coupling of lithiophilic pyridinic N on perforation edges and low tortuosity via graphene nanoperforation. Chem Eng J, 2023, 455140770.

[43]

DongW, WuZ, ZhuX, ShenD, ZhaoM, YangF, ChangQ, TangS, HongX, DongZ, YangS. Synergistic pyridinic N/pyrrolic N configurations in rGO/CNT composite sulfur hosts for high-performance lithium–sulfur batteries. Chem Eng J, 2024, 488150872.

[44]

ChenQ, LiT, HuangH, WangW, YuZ, LiuQ, LiuL. Pyridinic-N-rich single-atom vanadium catalysts boost conversion kinetics of polysulfides for high performance lithium–sulfur batteries. Nano Energy, 2025, 133110509.

[45]

SunW, XuL, SongZ, LinH, JinZ, WangW, WangA, HuangY. Coordination engineering based on graphitic carbon nitrides for long‐life and high‐capacity lithium–sulfur batteries. Adv Funct Mater, 2023.

[46]

ChenW, LeiT, QianT, LvW, HeW, WuC, LiuX, LiuJ, ChenB, YanC, XiongJ. A new hydrophilic binder enabling strongly anchoring polysulfides for high‐performance sulfur electrodes in lithium–sulfur battery. Adv Energy Mater, 2018.

[47]

HongXJ, SongCL, YangY, TanHC, LiGH, CaiYP, et al.. Cerium based metal-organic frameworks as an efficient separator coating catalyzing the conversion of polysulfides for high performance lithium–sulfur batteries. ACS Nano, 2019, 13(2): 1923-1931.

[48]

ChangH, DengH, WangY, WangS, CaoL, DongZ, TanT. Synthesis of large mesoporous carbon from cotton stalk for use as an anode for lithium-ion batteries. Biomass Bioenergy, 2022, 167106641.

[49]

WangJ, YiS, LiuJ, SunS, LiuY, YangD, et al.. Suppressing the shuttle effect and dendrite growth in lithium–sulfur batteries. ACS Nano, 2020, 14(8): 9819-9831.

[50]

DengDR, BaiCD, XueF, LeiJ, XuP, ZhengMS, et al.. Multifunctional ion-sieve constructed by 2D materials as an interlayer for Li–S batteries. ACS Appl Mater Interfaces, 2019, 11(12): 11474-11480.

[51]

PengQF, YuF, WangWK, WangAB, WangF, HuangYQ. Ultralight polyethylenimine/porous carbon modified separator as an effective polysulfide-blocking barrier for lithium–sulfur battery. Electrochim Acta, 2019, 299: 749-755.

[52]

XiaoS, HuangL, LvW, HeYB. A highly efficient ion and electron conductive interlayer to achieve low self-discharge of lithium–sulfur batteries. ACS Appl Mater Interfaces, 2022, 14(1): 1783-1790.

[53]

ZengG, LiuY, ChenD, ZhenC, HanY, HeW. Natural lepidolite enables fast polysulfide redox for high‐rate lithium sulfur batteries. Adv Energy Mater, 2021.

[54]

WangZ, LiuJ, ZhangBH, SunL, CongL, Alain MaugerL-L, JulienCM, XieH, SunH. Modulating molecular orbital energy level of lithium polysulfide for high-rate and long-life lithium-sulfur batteries. Energy Storage Mater, 2020, 24: 373-378.

[55]

XiaoYB, XiangYC, GuoSJ, WangJ, OuyangY, LiDX, et al.. An ultralight electroconductive metal-organic framework membrane for multistep catalytic conversion and molecular sieving in lithium–sulfur batteries. Energy Storage Mater, 2022, 51: 882-889.

[56]

WuX, LiuN, WangM, QiuY, GuanB, TianD, et al.. A class of catalysts of BiOX (X = Cl, Br, I) for anchoring polysulfides and accelerating redox reaction in lithium sulfur batteries. ACS Nano, 2019, 13(11): 13109-13115.

[57]

KongZ, LiY, WangY, ZhangY, ShenK, ChuX, WangH, WangJ, ZhanL. Monodispersed MnOx-CeO2 solid solution as superior electrocatalyst for Li2S precipitation and conversion. Chem Eng J, 2020, 392123697.

[58]

XiangY, XuL, YangL, YeY, GeZ, WuJ, DengW, ZouG, HouH, JiX. Natural stibnite for lithium-/sodium-ion batteries: carbon dots evoked high initial coulombic efficiency. Nano-Micro Lett, 2022.

[59]

ChenZ, ZhouJ, WangX, LiaoX, HuangX, ShiB. Natural collagen fiber-enabled facile synthesis of carbon@Fe3O4 core–shell nanofiber bundles and their application as ultrahigh-rate anode materials for Li-ion batteries. RSC Adv, 2016, 6(13): 10824-10830.

[60]

BrieskeDM, WarneckeA, SauerDU. Modeling the volumetric expansion of the lithium–sulfur battery considering charge and discharge profiles. Energy Storage Mater, 2023, 55: 289-300.

[61]

TaoR, TanS, LyuX, SunX-G, YangJ, XieD, DuZ, PupekKZ, DaiS, LiJ. In-situ ionothermal synthesis of nanoporous carbon/oxide composites: a new key to functional separators for stable lithium–sulfur batteries. Nano Energy, 2024, 130110091.

[62]

PengL, BaiY, LiH, QuM, WangZ, SunK. Boosting bidirectional sulfur conversion enabled by introducing boron-doped atoms and phosphorus vacancies in Ni2P for lithium-sulfur batteries. J Energy Chem, 2025, 100: 760-769.

[63]

LiuM, WuZ, LiuS, GuoT, ChenP, CaoX, PanS, ZhouT, PompiziiL, NajafovM, CoskunA, FuY. Accelerated reversible conversion of Li2S2 to Li2S by spidroin regulated Li+ flux for high-performance Li-sulfur batteries. Angew Chem Int Ed, 2024.

[64]

MenX, DengT, ChenL, CheJ, WangJ, WangJ. Suppressing surface oxidation of pyrite FeS2 by Cobalt doping in lithium sulfur batteries. Small, 2024.

[65]

WangZ, HuangW, WuH, WuY, ShiK, LiJ, ZhangW, LiuQ. 3D‐orbital high‐spin configuration driven from electronic modulation of Fe3O4/FeP heterostructures empowering efficient electrocatalyst for lithium−sulfur batteries. Adv Funct Mater, 2024.

[66]

MenX, DengT, CheJ, WangJ. Accelerating sulfur conversion kinetics via CoS2–MgS heterostructure for lithium sulfur batteries. J Mater Chem A, 2024, 12(46): 31972-31981.

Funding

National Natural Science Foundation of China(U21A2083)

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