Journals
[1] Cao, C.F., Yu, B.,* Guo, B. F., Hu, W.J., Sun, F.N., Zhang, Z.H., Li, S.N., Wu, W., Tang, L.C., Song, P., Wang, H.,* 2022, Bio-inspired, sustainable and mechanically robust graphene oxide-based hybrid networks for efficient fire protection and warning, Chemical Engineering Journal, 134516.
[2]Ma, Z., Liu, X., Xu, X., Liu, L., Yu, B.,* Maluk, C., Huang, G., Wang, H., Song, P*., 2021, Bioinspired, highly adhesive, nanostructured polymeric coatings for superhydrophobic fire-extinguishing thermal insulation foam. ACS Nano 15: 11667-11680.
[3] Yu, B., Yuen, A.C.Y., Xu, X., Zhang, Z.C., Yang, W.,* Lu, H., Fei, B.,* Yeoh, G.H., Song, P.,* Wang, H., 2021, Engineering MXene surface with POSS for reducing fire hazards of polystyrene with enhanced thermal stability. Journal of Hazardous Materials 401: 123342.
[4] Liu, C., Wu, W., Shi, Y.,* Yang, F., Liu, M., Chen, Z., Yu, B.,* Feng, Y., 2020, Creating MXene/reduced graphene oxide hybrid towards highly fire safe thermoplastic polyurethane nanocomposites, Composites Part B: Engineering 203: 108486.
[5] Shi, Y., Liu, C., Duan, Z., Yu, B.,* Liu, M., Song, P.,* 2020, Interface engineering of MXene towards super-tough and strong polymer nanocomposites with high ductility and excellent fire safety, Chemical Engineering Journal, 399:125829.
[6] Lin, B., Yuen, A.C.Y., Li, A.; Zhang, Y., Chen, T.B.Y., Yu, B.,* Lee, E.W.M., Peng, S., Yang, W.,* Lu, H.D., Chan, Q.N., Yeoh, G.H., Wang, C.H., 2020, MXene/chitosan nanocoating for flexible polyurethane foam towards remarkable fire hazards reductions, Journal of Hazardous Materials 381: 120952
[7] Yu, B., Tawiah, B., Wang, L.Q., Yuen, A.C.Y., Zhang, Z.C., Shen, L.L., Lin, B., Fei, B., Yang, W.,* Li, A., Zhu, S.E., Hu, E.Z., Lu, H.D., Yeoh, G.H., 2019, Interface decoration of exfoliated MXene ultra-thin nanosheets for fire and smoke suppressions of thermoplastic polyurethane elastomer, Journal of Hazardous Materials 374: 110-119.
[8] Shi, Y.,* Liu, C., Liu, L., Fu, L., Yu, B.,* Lv, Y., Yang, F., Song, P., 2019, Strengthening, toughing and thermally stable ultra-thin MXene nanosheets/polypropylene nanocomposites via nanoconfinement, Chemical Engineering Journal 378: 122267.
[9] Yu, B., Xing, W., Guo, W., Qiu, S., Wang, X.,* Lo, S., Hu, Y.,* 2016, Thermal exfoliation of hexagonal boron nitride for effective enhancements on thermal stability, flame retardancy and smoke suppression of epoxy resin nanocomposites via sol-gel process, Journal of Materials Chemistry A 4 (19): 7330-7340.
[10] Yu, B., Shi, Y., Yuan, B., Qiu, S., Xing, W., Hu, W.,* Song, L., Lo, S., Hu, Y.,* 2015, Enhanced thermal and flame retardant properties of flame-retardant-wrapped graphene/epoxy resin nanocomposites, Journal of Materials Chemistry A 3(15): 8034-8044.
Handbooks
[1] Fei, B., and Yu, B., “Recent advances in flame retardant textile applications,” Flame Retardant Polymeric Materials: A Handbook, Hu, Y., and Wang, X. (ed.), CRC Press, Taylor & Francis Group, 2020
[2] Hu, Y., Yu, B. and Song, L., “Novel fire-retardant coatings,” Novel Fire Retardant Polymers and Composite Materials, Wang D.Y. (ed.), Woodhead Publishing, Elsevier, 2017, pp 53-91.