Carbon Nanotube/Polyamic Acid Bilayer-Supported Composite Phase-Change Materials With Integrated Insulation and Thermal Conductivity Functions

Yingying Tian , Nannan Zheng , Zui Tao , Jun Tong , Tiantian Yuan , Xiubing Huang

Carbon Neutralization ›› 2025, Vol. 4 ›› Issue (5) : e70040

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Carbon Neutralization ›› 2025, Vol. 4 ›› Issue (5) : e70040 DOI: 10.1002/cnl2.70040
RESEARCH ARTICLE

Carbon Nanotube/Polyamic Acid Bilayer-Supported Composite Phase-Change Materials With Integrated Insulation and Thermal Conductivity Functions

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Abstract

Carbon aerogel supported phase change materials (PCMs) can confer multifunctional properties to ordinary PCMs and meet specific requirements in extreme environments. In this study, composite phase change materials (CPCMs) with integrated insulation and thermal conductivity functions were successfully developed through the physical integration of a thermal insulation layer and a thermal conductivity layer. The structurally stable carbonized polyimide (C-PI)/carbon nanotubes (CNTs) aerogel acts as the thermal conductivity layer substrate. The aerogel obtained from a polyamic acid salt (PAS) composite with carboxymethyl cellulose (CMC) was used for the thermal insulation layer. Then, polyethylene glycol was vacuum-impregnated into the integrated aerogel to prepare CPCMs with integrated insulation, thermal conductivity, and thermal energy storage functions. When the mass ratio of CNTs to PAS was 2, the enthalpy reaches 160.3 J/g and the PEG loading reaches 95.56%. Moreover, the presence of CNTs increased the thermal conductivity of the thermal conductive layer to 0.433 W/m K. In addition, the bilayer CPCMs can conduct heat quickly and also have a good thermal insulation effect. The all-in-one material achieves a perfect combination of dual functions and provides a new solution for thermal management of power devices. Furthermore, the bilayer CPCMs also have great application potential in the field of infrared stealth.

Keywords

carbon nanotube / phase change materials / polyimide aerogel / thermal insulation–conduction integration / thermal management

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Yingying Tian, Nannan Zheng, Zui Tao, Jun Tong, Tiantian Yuan, Xiubing Huang. Carbon Nanotube/Polyamic Acid Bilayer-Supported Composite Phase-Change Materials With Integrated Insulation and Thermal Conductivity Functions. Carbon Neutralization, 2025, 4(5): e70040 DOI:10.1002/cnl2.70040

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References

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

Y. Jia, Y. Jiang, Y. Pan, et al., “Recent Advances in Energy Storage and Applications of Form-Stable Phase Change Materials With Recyclable Skeleton,” Carbon Neutralization 3, no. 2 (2024): 313–343.
[2]

Y. Li, X. Huang, J. Lv, F. Wang, S. Jiang, and G. Wang, “Enzymolysis-Treated Wood-Derived Hierarchical Porous Carbon for Fluorescence-Functionalized Phase Change Materials,” Composites Part B— Engineering 234 (2022): 109735.
[3]

W. Lin, X. Yao, W. Zhao, Y. Pu, and S. Wang, “Pathways to Carbon Neutrality in the Built Environment: Phase Change Materials,” Green Carbon 2, no. 2 (2024): 197–204.
[4]

R. Yang, N. Zheng, Z. Yu, et al.,“Nickel Foam/Covalent-Organic Frameworks for Composite Phase Change Materials With Enhanced Solar-Thermal Energy Conversion and Storage Capacity,” Applied Thermal Engineering 230 (2023): 120808.
[5]

Y. Tian, R. Yang, H. Pan, N. Zheng, and X. Huang, “Biomass-Based Shape-Stabilized Phase Change Materials for Thermal Energy Storage and Multiple Energy Conversion,” Nano Energy 133 (2024): 110440.
[6]

Y. Li, X. Huang, G. Hai, J. Lv, Z. Tao, and G. Wang, “Crystallization of C18 in Mesoporous Silica: Effect of Surface Functionalization and Nanoconfinement,” Chemical Engineering Journal 428 (2022): 131075.
[7]

J. Tong, Z. Liu, Y. Liu, X. Huang, and G. Wang, “‘Back-to-Back’ Radial Layered Skeleton Converging Heat Flow to Assist in Thermal Conduction of Aramid Nanofibers/Graphene Phase Change Composite Materials,” Advanced Functional Materials 35, no. 1 (2025): 2411744.
[8]

N. Zheng, H. Pan, Z. Chai, et al., “Anisotropic Rotunda-Shaped Carboxymethylcellulose/Carbon Nanotube Aerogels Supported Phase Change Materials for Efficient Solar-Thermal Energy Conversion,” Chemsuschem 17, no. 7 (2024): e202301971.
[9]

J. Wang, X. Huang, H. Gao, A. Li, and C. Wang, “Construction of CNT@Cr-MIL-101-NH2 Hybrid Composite for Shape-Stabilized Phase Change Materials With Enhanced Thermal Conductivity,” Chemical Engineering Journal 350 (2018): 164–172.
[10]

R. Yang, X. Guo, H. Wu, et al., “Anisotropic Hemp-Stem-Derived Biochar Supported Phase Change Materials With Efficient Solar-Thermal Energy Conversion and Storage,” Biochar 4, no. 1 (2022): 4–15.
[11]

W. Luo, X. Hu, M. Zou, et al., “A Novel Low-Energy and Ultra-Easy Approach to Preparing Composite Phase Change Material With High Photo-/Electro-Thermal Energy Conversion and Storage,” Journal of Energy Storage 103 (2024): 114373.
[12]

X. Zhu, J. Liu, L. Zhang, W. Zhao, Y. Cao, and X. Liu, “Dual-Mode Mxene-Based Phase-Change Composite Towards Enhanced Photothermal Utilization and Excellent Infrared Stealth,” Small 20, no. 48 (2024): 2405694.
[13]

X. Dai, P. Ping, D. Kong, et al., “Heat Transfer Enhanced Inorganic Phase Change Material Compositing Carbon Nanotubes for Battery Thermal Management and Thermal Runaway Propagation Mitigation,” Journal of Energy Chemistry 89 (2024): 226–238.
[14]

G. Zhu, M. Zou, W. Luo, et al., “A Polyurethane Solid–Solid Phase Change Material for Flexible Use in Thermal Management,” Chemical Engineering Journal 488 (2024): 150930.
[15]

R. Yang, X. Huang, G. Zhao, Z. Liu, and G. Wang, “Ni@Rgo Into Nickel Foam for Composite Polyethylene Glycol and Erythritol Phase Change Materials,” Chemical Engineering Journal 451 (2023): 138900.
[16]

Z. Zhao, W. Liu, R. Du, et al., “Carbon-Based Phase Change Composites With Directional High Thermal Conductivity for Interface Thermal Management,” Chemical Engineering Journal 496 (2024): 154305.
[17]

Y. Hu, M. Zhang, B. Quan, et al., “Polyethylene Glycol Infiltrated Biomass-Derived Porous Carbon Phase Change Composites for Efficient Thermal Energy Storage,” Advanced Composites and Hybrid Materials 7, no. 2 (2024): 68.
[18]

Y. Li, N. Zheng, Y. Ren, et al., “Anisotropic and Hierarchical Porous Boron Nitride/Graphene Aerogels Supported Phase Change Materials for Efficient Solar-Thermal Energy Conversion,” Ceramics International 50, no. 11 (2024): 18923–18931.
[19]

G. Wang, L. Liu, X. Hu, et al., “Aerogel-Functionalized Phase Change Materials Toward Lightweight and Robust Thermal Management,” Small Methods (2025): 2500127.
[20]

L. Zhang, X. Li, E. Ding, et al., “Shape Memory Polyimide/Carbon Nanotube Composite Aerogels With Physical and Chemical Crosslinking Architectures for Thermal Insulating Applications,” Composite Science and Technology 251 (2024): 110588.
[21]

Z. Zheng, H. Liu, D. Wu, and X. Wang, “Polyimide/Mxene Hybrid Aerogel-Based Phase-Change Composites for Solar-Driven Seawater Desalination,” Chemical Engineering Journal 440 (2022): 135862.
[22]

J. Jing, H. Liu, and X. Wang, “Long-Term Infrared Stealth by Sandwich-Like Phase-Change Composites at Elevated Temperatures via Synergistic Emissivity and Thermal Regulation,” Advanced Functional Materials 34, no. 2 (2024): 2309269.
[23]

H. Hu, C. Wang, S. Xie, L. Zhang, J. Liu, and X. Li, “Polyethylene Glycol/Carboxymethyl Cellulose/Montmorillonite Composite Phase Change Materials for Thermal Management,” Journal of Energy Storage 105 (2025): 114714.
[24]

X. Zhang, X. Zhao, T. Xue, F. Yang, W. Fan, and T. Liu, “Bidirectional Anisotropic Polyimide/Bacterial Cellulose Aerogels by Freeze-Drying for Super-Thermal Insulation,” Chemical Engineering Journal 385 (2020): 123963.
[25]

Y. Wang, N. Pang, S. Liu, et al., “Flexible and High-Strength Mxene/Polyimide Nanofiber Aerogel Membranes Achieving Infrared Stealth Through Combined Thermal Control and Low Emissivity,” Chemical Engineering Journal 498 (2024): 155332.
[26]

P. Guo, W. Gu, J. Lu, et al., “Flexible Phase Change Composites Supported by Cu-Modified Carbon Felt: Enhanced Solar-to-Thermal Conversion and Shape Memory Properties,” Chemical Engineering Journal 504 (2025): 158832.
[27]

Y. Cao, M. Weng, M. H. H. Mahmoud, et al., “Flame-Retardant and Leakage-Proof Phase Change Composites Based on Mxene/Polyimide Aerogels Toward Solar Thermal Energy Harvesting,” Advanced Composites and Hybrid Materials 5, no. 2 (2022): 1253–1267.
[28]

T. Shi, H. Liu, and X. Wang, “Unidirectionally Structured Magnetic Phase-Change Composite Based on Carbonized Polyimide/Kevlar Nanofiber Complex Aerogel for Boosting Solar-Thermo-Electric Energy Conversion,” ACS Applied Materials & Interfaces 16, no. 8 (2024): 10180–10195.
[29]

T. Shi, J. Jing, and Z. Qian, et al., “Sandwich-Structured Fluorinated Polyimide Aerogel/Paraffin Phase-Change Composites Simultaneously Enables Gradient Thermal Protection and Electromagnetic Wave Transmission,” Advancement of Science 12, no. 5 (2024): 2411758.
[30]

S.-Q. Li, Y. Deng, J. Huang, P. Wang, G. Liu, and H.-L. Xie, “Light-Absorbing Copolymers of Polyimides as Efficient Photothermal Materials for Solar Water Evaporation,” Aggregate 4, no. 5 (2023): e371.
[31]

X. Zhou, X. Zhao, X. Li, et al., “Fabrication of Shape Memory Polyimides With Exploration of Their Activation Mechanisms,” Chemical Engineering Journal 477 (2023): 146776.
[32]

H. Zheng, X. Lu, and K. He, “In Situ Transmission Electron Microscopy and Artificial Intelligence Enabled Data Analytics for Energy Materials,” Journal of Energy Chemistry 68 (2022): 454–493.
[33]

T. Shi, Z. Zheng, H. Liu, D. Wu, and X. Wang, “Flexible and Foldable Composite Films Based on Polyimide/Phosphorene Hybrid Aerogel and Phase Change Material for Infrared Stealth and Thermal Camouflage,” Composites Science and Technology 217 (2022): 109127.
[34]

M. Su, G. Han, J. Gao, et al., “Carbon Welding on Graphene Skeleton for Phase Change Composites With High Thermal Conductivity for Solar-to-Heat Conversion,” Chemical Engineering Journal 427 (2022): 131665.
[35]

Y. Zhang, P. Wu, Y. Meng, R. Lu, S. Zhang, and B. Tang, “Flexible Phase Change Films With Enhanced Thermal Conductivity and Low Electrical Conductivity for Thermal Management,” Chemical Engineering Journal 464 (2023): 142650.
[36]

X. Li, T. Xu, W. Cao, et al., “Graphene/Carbon Fiber Network Constructed by Co-Carbonization Strategy for Functional Integrated Polyimide Composites With Enhanced Electromagnetic Shielding and Thermal Conductive Properties,” Chemical Engineering Journal 464 (2023): 142595.
[37]

I. Kholmanov, J. Kim, E. Ou, R. S. Ruoff, and L. Shi, “Continuous Carbon Nanotube–Ultrathin Graphite Hybrid Foams for Increased Thermal Conductivity and Suppressed Subcooling in Composite Phase Change Materials,” ACS Nano 9, no. 12 (2015): 11699–11707.
[38]

A. R. Akhiani, H. S. Cornelis Metselaar, B. C. Ang, M. Mehrali, and M. Mehrali, “Mxene/Rgo Grafted Sponge With an Integrated Hydrophobic Structure Towards Light-Driven Phase Change Composites,” Composites Part B—Engineering 264 (2023): 110885.
[39]

P. Cheng, H. Gao, X. Chen, et al., “Flexible Monolithic Phase Change Material Based on Carbon Nanotubes/Chitosan/Poly(Vinyl Alcohol),” Chemical Engineering Journal 397 (2020): 125330.
[40]

D. Liu, L. Shi, Q. Dai, et al., “Functionalization of Carbon Nanotubes for Multifunctional Applications,” Trends in Chemistry 6, no. 4 (2024): 186–210.
[41]

Y. Zhang, J.-W. Wang, Y.-J. Ma, Z.-L. Zhang, and L. Tao, “Polyimide Composites With Fluorinated Graphene and Functionalized Boron Nitride Nanosheets for Heat Dissipation,” ACS Applied Nano Materials 7, no. 5 (2024): 5009–5018.
[42]

L.-M. Peng, Z. Xu, J. Yang, et al., “Patternable Thermal Conductive Interface Materials Enabled by Vitrimeric Phase Change Materials,” Chemical Engineering Journal 455 (2023): 140891.
[43]

W. Zhang, Z. Ling, X. Fang, and Z. Zhang, “Anisotropically Conductive Mg(No3)2·6h2o/G-C3n4-Graphite Sheet Phase Change Material for Enhanced Photo-Thermal Storage,” Chemical Engineering Journal 430 (2022): 132997.
[44]

K. Jiao, L. Lu, T. Wen, and Q. Wang, “Endowing Photothermal Materials With Latent Heat Storage: A State-of-Art Review on Photothermal Pcms,” Chemical Engineering Journal 500 (2024): 156498.
[45]

B. Wan, X. Li, X. Zeng, and J.-W. Zha, “Covalent-Assisted Construction of ‘Scale-Like’ Boron Nitride/Polyimide Thermal Interface Materials With High Thermal Conductivity,” CompComm 45 (2024): 101803.
[46]

P. Liu, F. An, X. Lu, et al., “Highly Thermally Conductive Phase Change Composites With Excellent Solar-Thermal Conversion Efficiency and Satisfactory Shape Stability on the Basis of High-Quality Graphene-Based Aerogels,” Composites Science and Technology 201 (2021): 108492.
[47]

L.-S. Tang, Y.-C. Zhou, L. Zhou, et al., “Double-Layered and Shape-Stabilized Phase Change Materials With Enhanced Thermal Conduction and Reversible Thermochromism for Solar Thermoelectric Power Generation,” Chemical Engineering Journal 430 (2022): 132773.
[48]

R. Kokubu, N. Hara, A. Yamamoto, et al., “Study on the Diffusion Coefficients of Molecules in Precursor Varnishes and Solid Polyimides for Understanding the Polyimide Curing Process,” Industrial & Engineering Chemistry Research 63, no. 11 (2024): 4934–4941.
[49]

M. Li and C. Wang, “Preparation and Characterization of Go/Peg Photo-Thermal Conversion Form-Stable Composite Phase Change Materials,” Renewable Energy 141 (2019): 1005–1012.
[50]

D. Yan, W. Ming, S. Liu, et al., “Polyethylene Glycol (Peg)/Silicon Dioxide Grafted Aminopropyl Group and Carboxylic Multi-Walled Carbon Nanotubes (Sam) Composite as Phase Change Material for Light-to-Heat Energy Conversion and Storage,” Journal of Energy Storage 36 (2021): 102428.
[51]

J. Wang, Z. Wu, H. Xie, et al., “Effect of Different Soft Segment Contents on the Energy Storage Capacity and Photo–Thermal Performance of Polyurethane-Based/Graphene Oxide Composite Solid–Solid Phase Change Materials,” Polymers 14 (2022): 5161.
[52]

H. Yang, L. He, R. Liu, C. Ge, C. Ma, and X. Zhang, “Ultralight and Flexible Carbon-Based Phase Change Composites With High Porosity for Enhanced Shape Memory and Photothermal Conversion Performance,” Solar Energy Materials & Solar Cells 244 (2022): 111816.
[53]

X. Chen, L. Wang, Y. Gao, et al., “Co/N Co-Doped Flower-Like Carbon-Based Phase Change Materials toward Solar Energy Harvesting,” Aggregate 5 (2023): e413.
[54]

H. Yang, Y. Bai, C. Ge, S. Li, and X. Zhang, “High Thermal Conductivity of Carboxyl-Rich Carbon/Polyethylene Glycol Composites for Enhanced Photothermal Conversion and Latent Heat Storage,” Chinese Journal of Chemistry 39, no. 12 (2021): 3245–3254.
[55]

H. Pang, G. Li, L. Cheng, C. He, X. Wang, and X. Zhang, “3D Flower-Like Cuo@Peg Composite Phase Change Materials With Photo Response for Applications in Energy Conversion and Storage,” Journal of Energy Storage 82 (2024): 110537.

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2025 The Author(s). Carbon Neutralization published by Wenzhou University and John Wiley & Sons Australia, Ltd.

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