Hierarchically Structured CNT@Co-N-CNF Interlayers for Enhanced Lithium Polysulfide Confinement in Lithium-Sulfur Batteries

Seoye Shin , Dae Kyom Kim , Jeong Jun Park , San Moon , Je-Nam Lee , Jong Hyeok Park , Sang-Gil Woo , Jungdon Suk

Battery Energy ›› 2026, Vol. 5 ›› Issue (4) : e70128

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Battery Energy ›› 2026, Vol. 5 ›› Issue (4) :e70128 DOI: 10.1002/bte2.70128
RESEARCH ARTICLE
Hierarchically Structured CNT@Co-N-CNF Interlayers for Enhanced Lithium Polysulfide Confinement in Lithium-Sulfur Batteries
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Abstract

Lithium-sulfur batteries (LSBs) are considered promising candidates for high-energy-density storage systems. However, challenges such as the polysulfide shuttle effect and limited cycling stability hinder their commercialization. This study introduces a hierarchically structured interlayer, CNT @Co-N-CNF (CCNC), fabricated through a novel process that combines electrospinning with ZIF-67-derived carbonization. This interlayer uniquely integrates physical and chemical confinement mechanisms for lithium polysulfides (LiPSs) by leveraging a conductive carbon nanotube (CNT) network, nitrogen (N)-doping, and embedded cobalt species. Designed to enhance sulfur utilization and effectively suppress LiPS migration, the 50-CCNC interlayer demonstrates an initial discharge capacity of 1137.4 mAh gs-1, along with excellent cycling stability in coin cell configurations. Furthermore, its practical potential is validated in a pouch stack cell configuration, achieving an initial capacity of 1082.7 mAh gs-1and retaining 92.46% of its capacity after 40 cycles. These findings underscore the interlayer's effectiveness in addressing key challenges for large-scale LSB applications and represent a significant step toward the commercialization of high-energy-density LSB technology.

Keywords

carbon nanofiber interlayers / lithium-sulfur batteries / polysulfide suppression / stack cell pouch

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Seoye Shin, Dae Kyom Kim, Jeong Jun Park, San Moon, Je-Nam Lee, Jong Hyeok Park, Sang-Gil Woo, Jungdon Suk. Hierarchically Structured CNT@Co-N-CNF Interlayers for Enhanced Lithium Polysulfide Confinement in Lithium-Sulfur Batteries. Battery Energy, 2026, 5 (4) : e70128 DOI:10.1002/bte2.70128

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References

[1]

J. B. Goodenough and Y. Kim, “Challenges for Rechargeable Li Batteries,” Chemistry of Materials 22 (2010): 587–603.

[2]

K. Liu, Y. Liu, D. Lin, A. Pei, and Y. Cui. Science Advances 4 (2018): eaas9820.

[3]

M. J. M. Al Essa, “Applications and Challenges of Lithium-Sulfur Electrochemical Batteries,” Journal of Electrochemical Science and Technology 15 (2024): 1–13.

[4]

W. Kang, N. Deng, J. Ju, et al., “A Review of Recent Developments in Rechargeable Lithium–Sulfur Batteries,” Nanoscale 8 (2016): 16541–16588.

[5]

A. Manthiram, S. H. Chung, and C. Zu, “Lithium–Sulfur Batteries: Progress and Prospects,” Advanced Materials 27 (2015): 1980–2006.

[6]

G. Xu, B. Ding, J. Pan, P. Nie, L. Shen, and X. Zhang, “High Performance Lithium–Sulfur Batteries: Advances and Challenges,” Journal of Materials Chemistry A: Materials for Energy and Sustainability 2 (2014): 12662–12676.

[7]

M. Zhao, B.-Q. Li, X.-Q. Zhang, J.-Q. Huang, and Q. Zhang, “A Perspective Toward Practical Lithium–Sulfur Batteries,” ACS Central Science 6 (2020): 1095–1104.

[8]

M. Wild, L. O'neill, T. Zhang, et al. Energy & Environmental Science 8 (2015): 3477.

[9]

K. T. Alali, J. Liu, Q. Liu, R. Li, K. Aljebawi, and J. Wang, “Grown Carbon Nanotubes on Electrospun Carbon Nanofibers as a 3D Carbon Nanomaterial for High Energy Storage Performance,” ChemistrySelect 4 (2019): 5437–5458.

[10]

J.-Q. Huang, Q. Zhang, and F. Wei, “Multi-Functional Separator/Interlayer System for High-Stable Lithium-Sulfur Batteries: Progress and Prospects,” Energy Storage Materials 1 (2015): 127–145.

[11]

Y. Qin, C. Zhen, C. Zeng, et al. Small 21 (2025): e10220.

[12]

Y. Qin, Y. Pang, C. Zeng, et al., “Understanding the Crucial Roles of Natural Clinochlore in Reinforcing Li–S Batteries,” Journal of Materials Chemistry A 12 (2024): 30655–30666.

[13]

C. Zhen, W. He, and D. Chen. Small 19 (2023): 2302548.

[14]

F. Shi, J. Yu, C. Chen, D. S. P. Lau, W. Lv, and Z. L. Xu. Advanced Energy Materials 11 (2021): 2102058.

[15]

L. Fan, M. Li, X. Li, W. Xiao, Z. Chen, and J. Lu, “Interlayer Material Selection for Lithium-Sulfur Batteries,” Joule 3 (2019): 361–386.

[16]

B. Song, H. Zhao, G. Zhao, et al., “Bifunctional Carbon Nanofibrous Interlayer Embedded With Cobalt Single Atoms for Polysulfides Trapping and Catalysis in Lithium-Sulfur Batteries,” Chemical Engineering Journal 460 (2023): 141907.

[17]

X. Zuo, M. Zhen, D. Liu, et al., “A Multifunctional Catalytic Interlayer for Propelling Solid–Solid Conversion Kinetics of Li2S2to Li2S in Lithium–Sulfur Batteries,” Advanced Functional Materials 33 (2023): 2214206.

[18]

T. Z. Zhuang, J. Q. Huang, H. J. Peng, et al., “Rational Integration of Polypropylene/Graphene Oxide/Nafion as Ternary-Layered Separator to Retard the Shuttle of Polysulfides for Lithium–Sulfur Batteries,” Small 12 (2016): 381–389.

[19]

S. Tu, X. Chen, X. Zhao, et al. Advanced Materials 30 (2018): 1804581.

[20]

Z. Song, X. Lu, Q. Hu, et al., “Synergistic Confining Polysulfides by Rational Design a N/P Co-Doped Carbon as Sulfur Host and Functional Interlayer for High-Performance Lithium–Sulfur Batteries,” Journal of Power Sources 421 (2019): 23–31.

[21]

M. Tian, F. Pei, M. Yao, et al., “Ultrathin Mof Nanosheet Assembled Highly Oriented Microporous Membrane as an Interlayer for Lithium-Sulfur Batteries,” Energy Storage Materials 21 (2019): 14–21.

[22]

S. Kaewruang, P. Chiochan, N. Phattharasupakun, et al., “Strong Adsorption of Lithium Polysulfides on Ethylenediamine-Functionalized Carbon Fiber Paper Interlayer Providing Excellent Capacity Retention of Lithium-Sulfur Batteries,” Carbon 123 (2017): 492–501.

[23]

R. Singhal, S.-H. Chung, A. Manthiram, and V. Kalra, “A Free-Standing Carbon Nanofiber Interlayer for High-Performance Lithium–Sulfur Batteries,” Journal of Materials Chemistry A 3 (2015): 4530–4538.

[24]

J.-Q. Huang, Z.-L. Xu, S. Abouali, M. Akbari Garakani, and J.-K. Kim, “Porous Graphene Oxide/Carbon Nanotube Hybrid Films as Interlayer for Lithium-Sulfur Batteries,” Carbon 99 (2016): 624–632.

[25]

L. Chen, H. Yu, W. Li, M. Dirican, Y. Liu, and X. Zhang, “Interlayer Design Based on Carbon Materials for Lithium–Sulfur Batteries: A Review,” Journal of Materials Chemistry A 8 (2020): 10709–10735.

[26]

D. Zhu, T. Long, B. Xu, et al., “Recent Advances in Interlayer and Separator Engineering for Lithium-Sulfur Batteries,” Journal of Energy Chemistry 57 (2021): 41–60.

[27]

Y. Zheng, S. Zheng, H. Xue, and H. Pang, “Metal–Organic Frameworks for Lithium–Sulfur Batteries,” Journal of Materials Chemistry A 7 (2019): 3469–3491.

[28]

G. Zhong, D. Liu, and J. Zhang, “The Application of ZIF-67 and Its Derivatives: Adsorption, Separation, Electrochemistry and Catalysts,” Journal of Materials Chemistry A 6 (2018): 1887–1899.

[29]

J. Tang and Y. Yamauchi, “MOF Morphologies in Control,” Nature Chemistry 8 (2016): 638–639.

[30]

J. Phung, X. Zhang, W. Deng, and G. Li, “An Overview of MOF-Based Separators for Lithium-Sulfur Batteries,” Sustainable Materials and Technologies 31 (2022): e00374.

[31]

J. Zhao, C. Liu, H. Deng, et al., “In-Situ Catalytic Growth Carbon Nanotubes From Metal Organic Frameworks for High Performance Lithium-Sulfur Batteries,” Materials Today Energy 8 (2018): 134–142.

[32]

Y. M. Chen, L. Yu, and X. W. Lou, “Hierarchical Tubular Structures Composed of Co3O4Hollow Nanoparticles and Carbon Nanotubes for Lithium Storage,” Angewandte Chemie International Edition 55 (2016): 5990–5993.

[33]

W. E. Teo and S. Ramakrishna, “A Review on Electrospinning Design and Nanofibre Assemblies,” Nanotechnology 17 (2006): R89–R106.

[34]

B. Joshi, E. Samuel, Y. Kim, A. L. Yarin, M. T. Swihart, and S. S. Yoon, “Progress and Potential of Electrospinning-Derived Substrate-Free and Binder-Free Lithium-Ion Battery Electrodes,” Chemical Engineering Journal 430 (2022): 132876.

[35]

J. Zhu, H. Cheng, P. Zhu, Y. Li, Q. Gao, and X. Zhang, “Electrospun Nanofibers Enabled Advanced Lithium–Sulfur Batteries,” Accounts of Materials Research 3 (2022): 149–160.

[36]

J. Liu, H. Wang, X. Yi, et al., “pH-Sensitive Dissociable Nanoscale Coordination Polymers With Drug Loading for Synergistically Enhanced Chemoradiotherapy,” Advanced Functional Materials 29 (2019): 1905467.

[37]

V. J. Ariyamparambil and B. Kandasubramanian, “A Mini-Review on the Recent Advancement of Electrospun MOF-Derived Nanofibers for Energy Storage,” Chemical Engineering Journal Advances 11 (2022): 100355.

[38]

Z. Shan, Y. He, N. Liu, J. Li, M. Li, and Y. Zhang, “Spontaneously Rooting Carbon Nanotube Incorporated N-Doped Carbon Nanofibers as Efficient Sulfur Host Toward High Performance Lithium-Sulfur Batteries,” Applied Surface Science 539 (2021): 148209.

[39]

Y. Zhu, X. Wu, M. Li, et al. ACS Sustainable Chemistry & Engineering 10 (2022): 776.

[40]

J. Tahalyani, M. J. Akhtar, and K. K. Kar, “Flexible, Stretchable, and Lightweight Hierarchical Carbon-Nanotube-Decorated Carbon Fiber Structures for Microwave Absorption,” ACS Applied Nano Materials 6 (2023): 11888–11901.

[41]

R. Chen, Y. Hu, Z. Shen, et al., “Facile Fabrication of Foldable Electrospun Polyacrylonitrile-Based Carbon Nanofibers for Flexible Lithium-Ion Batteries,” Journal of Materials Chemistry A 5 (2017): 12914–12921.

[42]

P. Musiol, P. Szatkowski, M. Gubernat, A. Weselucha-Birczynska, and S. Blazewicz, “Comparative Study of the Structure and Microstructure of PAN-Based Nano- and Micro-Carbon Fibers,” Ceramics International 42 (2016): 11603–11610.

[43]

C. F. Holder and R. E. Schaak, “Tutorial on Powder X-Ray Diffraction for Characterizing Nanoscale Materials,” ACS Nano 13 (2019): 7359–7365.

[44]

L. Jin, Z. Fu, X. Qian, et al., “Co-N/KB Porous Hybrid Derived From Zif 67/KB as a Separator Modification Material for Lithium-Sulfur Batteries,” Electrochimica Acta 382 (2021): 138282.

[45]

S. Li, G. Ren, M. N. F. Hoque, Z. Dong, J. Warzywoda, and Z. Fan, “Carbonized Cellulose Paper as an Effective Interlayer in Lithium-Sulfur Batteries,” Applied Surface Science 396 (2017): 637–643.

[46]

D. Potoczna-Petru, “The Interaction of Model Cobalt Catalysts With Carbon,” Carbon 29 (1991): 73–79.

[47]

J. Zhu, R. Pitcheri, T. Kang, et al., “A Polysulfide-Trapping Interlayer Constructed by Boron and Nitrogen Co-Doped Carbon Nanofibers for Long-Life Lithium Sulfur Batteries,” Journal of Electroanalytical Chemistry 833 (2019): 151–159.

[48]

A. V. Ravindra, B. C. Behera, and P. Padhan, “Laser Induced Structural Phase Transformation of Cobalt Oxides Nanostructures,” Journal of Nanoscience and Nanotechnology 14 (2014): 5591–5595.

[49]

C.-W. Tang, C.-B. Wang, and S.-H. Chien, “Characterization of Cobalt Oxides Studied by FT-IR, Raman, TPR and TG-MS,” Thermochimica Acta 473 (2008): 68–73.

[50]

J. M. Holden, P. Zhou, X.-X. Bi, et al., “Raman Scattering From Nanoscale Carbons Generated in a Cobalt-Catalyzed Carbon Plasma,” Chemical Physics Letters 220 (1994): 186–191.

[51]

M. Doumeng, L. Makhlouf, F. Berthet, et al., “A Comparative Study of the Crystallinity of Polyetheretherketone by Using Density, DSC, XRD, and Raman Spectroscopy Techniques,” Polymer Testing 93 (2021): 106878.

[52]

Y. Xie, J. Cao, X. Wang, et al., “MOF-Derived Bifunctional Co0.85Se Nanoparticles Embedded in N-Doped Carbon Nanosheet Arrays as Efficient Sulfur Hosts for Lithium–Sulfur Batteries,” Nano Letters 21 (2021): 8579–8586.

[53]

Q. Pang, J. Tang, H. Huang, et al., “A Nitrogen and Sulfur Dual-Doped Carbon Derived From Polyrhodanine@Cellulose for Advanced Lithium–Sulfur Batteries,” Advanced Materials 27 (2015): 6021–6028.

[54]

Y. Zhao, Z. Wang, X. Zhao, et al. Energy & Fuels 34 (2020): 10188.

[55]

Z. Kong, H. Xu, G. Xu, et al., “Cobalt Nanoparticles & Nitrogen-Doped Carbon Nanotubes@Hollow Carbon With High Catalytic Ability for High-Performance Lithium Sulfur Batteries,” Journal of Colloid and Interface Science 648 (2023): 846–854.

[56]

X. Chen, F. Zhang, D. Lan, et al., “State-of-The-Art Synthesis Strategy for Nitrogen-Doped Carbon-Based Electromagnetic Wave Absorbers: From the Perspective of Nitrogen Source,” Advanced Composites and Hybrid Materials 6 (2023): 220.

[57]

S. Jin, M. Wang, Y. Zhong, et al., “A Nitrogen-Doped Carbon Skeleton Derived From Biomass as Conductive Agent for Electrochemically Stable Cathode of All-Solid-State Lithium-Sulfur Batteries,” Materials Today Sustainability 21 (2023): 100281.

[58]

D. Liu, Z. Wang, Z. Guo, Y. Tian, and C. Wang, “Electrospun CuCoN0.6 Coating Necklace-Like N-Doped Carbon Nanofibers for High Performance Lithium-Sulfur Batteries,” Journal of Colloid and Interface Science 645 (2023): 705–714.

[59]

R. Zhu, J. Ding, J. Yang, et al., “Quasi-ZIF-67 for Boosted Oxygen Evolution Reaction Catalytic Activity via a Low Temperature Calcination,” ACS Applied Materials & Interfaces 12 (2020): 25037–25041.

[60]

S. A. Rincón-Ortiz, J. H. Quintero-Orozco, R. Ospina, S. A. Rincón-Ortiz, J. H. Quintero-Orozco, and R. Ospina, “ZnO by AgLα, Hard X-Ray Photoelectron Spectroscopy,” Surface Science Spectra 30 (2023): 24027, https://doi.org/10.1116/6.0003126.

[61]

C. Ehrhardt, M. Gjikaj, and W. Brockner, “Thermal Decomposition of Cobalt Nitrato Compounds: Preparation of Anhydrous Cobalt(II) Nitrate and Its Characterisation by Infrared and Raman Spectra,” Thermochimica Acta 432 (2005): 36–40.

[62]

H. Wang, C. Xu, X. Du, G. Liu, W. Han, and J. Li. Chemical Engineering Journal 471 (2023): 144338.

[63]

D. Xiong, S. Huang, D. Fang, et al. Small 17 (2021): 2007442.

[64]

M. Thommes, K. Kaneko, A. V. Neimark, et al., “Physisorption of Gases, With Special Reference to the Evaluation of Surface Area and Pore Size Distribution (IUPAC Technical Report,” Pure and Applied Chemistry 87 (2015): 1051–1069.

[65]

X. Xiang, J. Y. Wu, Q. X. Shi, et al., “Mesoporous Silica Nanoplates Facilitating Fast Li+ Diffusion as Effective Polysulfide-Trapping Materials for Lithium–Sulfur Batteries,” Journal of Materials Chemistry A 7 (2019): 9110–9119.

[66]

W. Yao, J. Xu, Y. Cao, et al., “Dynamic Intercalation–Conversion Site Supported Ultrathin 2D Mesoporous SnO2/SnSe2 Hybrid as Bifunctional Polysulfide Immobilizer and Lithium Regulator for Lithium–Sulfur Chemistry,” ACS Nano 16 (2022): 10783–10797.

[67]

S.-H. Chung and A. Manthiram, “Lithium–Sulfur Batteries With Superior Cycle Stability by Employing Porous Current Collectors,” Electrochimica Acta 107 (2013): 569–576.

[68]

R. Li, H. Peng, Q. Wu, et al., “Sandwich-Like Catalyst–Carbon–Catalyst Trilayer Structure as a Compact 2D Host for Highly Stable Lithium–Sulfur Batteries,” Angewandte Chemie International Edition 59 (2020): 12129–12138.

[69]

J. Qian, F. Wang, Y. Li, et al. Advanced Functional Materials 30 (2020): 2000742.

[70]

X. Yu, Y. Yin, C. Ma, et al. Chemical Engineering Science 268 (2023): 118400.

[71]

Y. X. Yin, S. Xin, Y. G. Guo, and L. J. Wan, “Lithium–Sulfur Batteries: Electrochemistry, Materials, and Prospects,” Angewandte Chemie International Edition 52 (2013): 13186–13200.

[72]

L. Yan, N. Luo, W. Kong, et al., “Enhanced Performance of Lithium-Sulfur Batteries With an Ultrathin and Lightweight MoS2/Carbon Nanotube Interlayer,” Journal of Power Sources 389 (2018): 169–177.

[73]

P. Guo, D. Liu, Z. Liu, X. Shang, Q. Liu, and D. He, “Dual Functional MoS2/Graphene Interlayer as an Efficient Polysulfide Barrier for Advanced Lithium-Sulfur Batteries,” Electrochimica Acta 256 (2017): 28–36.

[74]

R. Fang, G. Li, S. Zhao, et al., “Single-Wall Carbon Nanotube Network Enabled Ultrahigh Sulfur-Content Electrodes for High-Performance Lithium-Sulfur Batteries,” Nano Energy 42 (2017): 205–214.

[75]

N. A. Cañas, K. Hirose, B. Pascucci, N. Wagner, K. A. Friedrich, and R. Hiesgen, “Investigations of Lithium–Sulfur Batteries Using Electrochemical Impedance Spectroscopy,” Electrochimica Acta 97 (2013): 42–51.

[76]

S. Sung, B. H. Kim, S. Lee, S. Choi, and W. Y. Yoon, “Increasing Sulfur Utilization in Lithium-Sulfur Batteries by a Co-MOF-74@MWCNT Interlayer,” Journal of Energy Chemistry 60 (2021): 186–193.

[77]

C. Zhang, B. Fei, D. Yang, et al. Advanced Functional Materials 32 (2022): 2201322.

[78]

S. Jiang, M. Chen, X. Wang, et al., “Honeycomb-Like Nitrogen and Sulfur Dual-Doped Hierarchical Porous Biomass Carbon Bifunctional Interlayer for Advanced Lithium-Sulfur Batteries,” Chemical Engineering Journal 355 (2019): 478–486.

[79]

Z. Xiao, Z. Yang, L. Wang, et al., “A Lightweight TiO2/Graphene Interlayer, Applied as a Highly Effective Polysulfide Absorbent for Fast, Long-Life Lithium–Sulfur Batteries,” Advanced Materials 27 (2015): 2891–2898.

[80]

W. Hua, Z. Yang, H. Nie, et al., “Polysulfide-Scission Reagents for the Suppression of the Shuttle Effect in Lithium–Sulfur Batteries,” ACS Nano 11 (2017): 2209–2218.

[81]

S. Ji, S. K. Kim, S. H. Choi, et al., “Yttria-Stabilized Zirconia Nanoparticles─Carbon Nanotube Composite as a Polysulfide-Capturing Lithium–Sulfur Battery Separator,” ACS Applied Energy Materials 5 (2022): 12196–12205.

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