Journals

[1] Luo, Z., Zhang, P., Hou, H., Li, Y., Li, B., Yi, Y., Xu, L., Meng, T., Geng, Z., Chen, M.K. and Zhao, Y., 2025. Colorimetric Thermography by a Long‐Infrared Dual‐Band Metalens. Advanced Science, 12(2), p.2408683.

[2] Chen, Z., Zhang, P., Wang, T., Wu, X., Zhang, Z., Zhao, Y. and Gu, P., 2025. Normal Dynamic Adhesion of an Infinite Elastomer Layer on a Statistically Rough Substrate. Journal of the Mechanics and Physics of Solids, p.106040.

[3] Chen, Z., Sun, X., Zhu, Y., Wu, X., Zhang, Z., Wu, H., Zhao, Y. and Gu, P., 2025. Delamination Behavior and Pull-Off Force Analysis of Square Cross-Section Elastomers. International Journal of Mechanical Sciences, p.110197.

[4] Meng, T., Zhang, P., Zhong, H., Zhu, H., Zhang, H., Xu, D. and Zhao, Y., 2024. Phonon Transport in Supramolecular Polymers Regulated by Hydrogen Bonds. Nano Letters, 24(44), pp.14095-14101.

[5] Meng, T., Zhang, X., Yao, J., Zhang, W., Zhong, H., Zhu, H., Zhang, Y., Zhang, H., Zhang, P., Lu, H. and Zhao, Y., 2024. Quantum confinement and energy filtering effect enhancing the thermoelectric power factor of InGaAs with buried ErAs nanoparticles. Applied Physics Letters, 125(4).

[6] Zhong, H., Meng, T., Ding, W., Xiao, Y. and Zhang, P., 2024. Achieving a Porous PDMS Film for Passive Cooling through the Utilization of Ultrafine NaCl Sacrificial Templates. ACS omega, 10(1), pp.1012-1018.

[7] Luo, Z., Hou, H., Meng, T., Li, Y., Wang, T., Yi, Y., Xu, L., Chen, Z., Zhong, H., Feng, Y. and Zhang, P., 2024. Optomechanical Infrared Detector Monolithically Integrated with Micro-Metalens Array. ACS Photonics, 11(11), pp.4597-4605.

[8] Yi, Y., Zhang, P., Chen, Z., Zhang, H., Luo, Z., Zhang, G., Li, W. and Zhao, Y., 2024. A demosaicking method based on an inter-channel correlation model for DoFP polarimeter. Optics and Lasers in Engineering, 181, p.108388.

[9] Wang, T., Gu, P., Gao, T., Li, H., Meng, T., Zhang, P. and Zhao, Y., 2024. Ladybug-inspired hierarchical composite adhesives for enhanced surface adaptability. Smart Materials and Structures, 33(9), p.095026.

[10] Zhang, P., Hou, H., Luo, Z., Feng, Y., Zhong, H., Zhang, H., Meng, T. and Zhao, Y., 2024. High Sensitivity and Rapid Response Optomechanical Uncooled Infrared Detector From Self-Assembled Super-Aligned Carbon Nanotubes Film. Journal of Microelectromechanical Systems.

[11] Hayat, B., Yafei, W., Yilin, W., Huwang, H., Peng, Z. and Yang, Z., 2023. Investigation of heat transfer performance of double-walled pipes of heat exchanger for power plant applications. International Communications in Heat and Mass Transfer, 149, p.107115.

[12] Luo, Z., Hou, H., Zhang, Y., Li, W., Zhang, P. and Zhao, Y., 2023. Optimal design of optomechanical uncooled infrared focal plane array with integrated metalens. Physica Scripta, 99(1), p.015510.

[13] Zhang, H., Yi, Y., Wang, Y., Hou, H., Meng, T., Zhang, P. and Zhao, Y., 2023. Pixelated micropolarizer array based on carbon nanotube films. Nanomaterials, 13(3), p.391.

[14] Zhang, H., Wang, Y., Zhang, P., Hou, H. and Zhao, Y., 2022. Investigation and optimization of polarization properties of self-assembled carbon nanotube films. Nanotechnology, 33(19), p.195702.

[15] Zhang, Y., Li, W., Gao, Z., Liu, Y., Zhang, P. and Zhao, Y., 2022. Digital-image-correlation-based thermomechanical diagnostics of Bismuth Telluride pillars in a thermoelectric cooler. Optics and Lasers in Engineering, 151, p.106905.

[16] Hou, H., Zhang, Y., Luo, Z., Zhang, P. and Zhao, Y., 2022. Design and fabrication of monolithically integrated metalens for higher effective fill factor in long-wave infrared detectors. Optics and Lasers in Engineering, 150, p.106849.

[17] Wang, T., Zhang, P., Yang, X., Zhang, Y., Zhang, J., He, X., Gu, P., Gong, X. and Zhao, Y., 2022. Rapidly switchable double-layered adhesive modified by magnetic field. Chemical Engineering Journal, 438, p.135441.

[18] Zhao, J., Zhao, Y., An, J., Yuan, C., Zhao, Y., Xiang, Y. and Yang, J., 2021. Thermally conductive silicone composites modified by graphene-oxide aerogel beads loaded with phase change materials as efficient heat sinks. Applied Thermal Engineering, 189, p.116713.

[19] Chen, Z., Cheng, G., Zhu, Y., Wu, H., Dong, E., Gu, P. and Zhao, Y., 2021. Biomimetic polydimethylsiloxane (PDMS)/carbon fiber lamellar adhesive composite in thermal vacuum environment. International Journal of Adhesion and Adhesives, 105, p.102778.

[20] Zhong, H., Li, Y., Zhang, P., Gao, S., Liu, B., Wang, Y., Meng, T., Zhou, Y., Hou, H., Xue, C. and Zhao, Y., 2021. Hierarchically hollow microfibers as a scalable and effective thermal insulating cooler for buildings. ACS nano, 15(6), pp.10076-10083.

[21] Meng, T., Sun, Y., Tong, C., Zhang, P., Xu, D., Yang, J., Gu, P., Yang, J. and Zhao, Y., 2021. Solid-state thermal memory of temperature-responsive polymer induced by hydrogen bonds. Nano Letters, 21(9), pp.3843-3848.

[22] Yang, X., Zhong, H., Zhang, P., Wang, T., Zhang, Y., Gu, P. and Zhao, Y., 2021. Ladybug inspired double‐layered adhesive with enhanced robustness of surface roughness. ChemistrySelect, 6(4), pp.640-646.

[23] Zhang, P., Guo, J., Hou, H., Zhang, Y., Yang, X., Zhong, H., Chen, L. and Zhao, Y., 2020. Highly aligned carbon nanotube‐based bi‐material microactuators with reduced intertube slipping. ChemNanoMat, 6(3), pp.404-411.

[24] Zhong, H., Zhang, P., Li, Y., Yang, X., Zhao, Y. and Wang, Z., 2020. Highly solar-reflective structures for daytime radiative cooling under high humidity. ACS Applied Materials & Interfaces, 12(46), pp.51409-51417.

[25] Yang, X., Chen, L., Zhang, P., Zhong, H., Zhang, Y., Zhang, R., Gu, P. and Zhao, Y., 2020. Investigation of the relationship between adhesion force and mechanical behavior of vertically aligned carbon nanotube arrays. Nanotechnology, 31(29), p.295701.

[26] Yuan, C., Wang, Q., Wang, Y. and Zhao, Y., 2019. Inhibition effect of different interstitial materials on thermal runaway propagation in the cylindrical lithium-ion battery module. Applied thermal engineering, 153, pp.39-50.

[27] Zhong, H., Pei, Y., Hu, Z., Zhang, P., Guo, J., Gong, X. and Zhao, Y., 2019. A study of the heat transfer properties of CIP doped magnetorheological elastomers. Smart Materials and Structures, 28(2), p.025027.

[28] He, D., Cheng, G., Tang, L., Chen, L., Li, S., Gu, P. and Zhao, Y., 2018. Research on adhesive properties of polydimethylsiloxane-carbon fiber composite material. International Journal of Adhesion and Adhesives, 86, pp.35-39.

[29] Chen, L., Ju, B., Feng, Z. and Zhao, Y., 2018. Vertically aligned carbon nanotube arrays as thermal interface material for vibrational structure of piezoelectric transformer. Smart Materials and Structures, 27(7), p.075007.

[30] Pei, Y., Zhong, H., Wang, M., Zhang, P. and Zhao, Y., 2018. Effect of contact pressure on the performance of carbon nanotube arrays thermal interface material. Nanomaterials, 8(9), p.732.

[31] Liu, Y., Dai, C., Pei, Y., Zhang, P., Tao, Y., Chen, Y. and Zhao, Y., 2018. Thermal interfacial coupling between electroplated copper and indium. Materials Research Express, 5(9), p.096416.

[32] Zhao, Y., Chu, R.S., Grigoropoulos, C.P., Dubon, O.D. and Majumdar, A., 2016. Array volume fraction-dependent thermal transport properties of vertically aligned carbon nanotube arrays. Journal of Heat Transfer, 138(9), p.092401.

[33] Zhang, X., Yu, Z., Wang, C., Zarrouk, D., Seo, J.W.T., Cheng, J.C., Buchan, A.D., Takei, K., Zhao, Y., Ager, J.W. and Zhang, J., 2014. Photoactuators and motors based on carbon nanotubes with selective chirality distributions. Nature communications, 5(1), p.2983.

[34]李昊宇, 王涛, 陈子健, 赵旸 and 辜萍, 2024. 调控界面应力分布增强干黏附材料的黏附力. Journal of Functional Polymers, 37(5).

[35]童晨, 裴娱, 孟婷, 张鹏, 杨晓晨, 张熠远 and 赵旸, 2021. 基于相敏瞬态热反射系统的多层热界面材料的拟合研究. 实验力学, 36(1), pp.51-61.

[36]李诗瑶, 赵旸, 程刚, 何东京, 辜萍, 隋凡平, 张若谷, 陈烈 and 唐玲, 2019. 基底对 PDMS-碳纤维复合材料粘附性能的影响. 实验力学, 34(1), pp.23-28.

[37]戴超伦, 刘亚 and 赵旸, 2018. 铬粘附层对金/二氧化硅界面热导影响研究. APPLIED LASER, 38(6), pp.968-974.