PSI - Issue 64

548 Alamgir Khan et al. / Procedia Structural Integrity 64 (2024) 539–548 Alamgir khan / Structural Integrity Procedia 00 (2019) 000–000 Amditis, Y. Damigos, C.J.P.S.I. Bouklas, Strain monitoring system for steel and concrete structures, (2018). Journal of Procedia Structural Integrity 10, 25-32. [4] Z. Wang, T. Shao, H. Zhang, J. Huo, J. Liu, T. Zhang, X. Ji, H. Zhang, J. Wang, H.J.C. Guo, B. Principles, properties and applications of smart conductive cement-based composites: a state-of-the-art review, (2023). Journal of Construction and Building Materials 408, 133569. [5] A. Dinesh, D. Suji, M.J.J.o.B.E. Pichumani, Electro-mechanical investigations of steel fiber reinforced self sensing cement composite and their implications for real-time structural health monitoring, (2022). Journal of Building Engineering 51, 104343. [6] M. Hambach, H. Möller, T. Neumann, D.J.C.P.B.E. Volkmer, Carbon fibre reinforced cement-based composites as smart floor heating materials, (2016). Journal of Composites Part B 90, 465-470. [7] D. Lu, X. Shi, H.S. Wong, Z. Jiang, J.J.C. Zhong, B., Graphene coated sand for smart cement composites, (2022). Journal of Construction and Building Materials 346, 128313. [8] T.N. Abebe, B.-H. Woo, H.G. Kim, J.-S.J.C. Ryou, Real-time monitoring of self-sensing cementitious composite incorporating hybrid silicon carbide and graphite for enhanced structural health monitoring, 2024). Journal of Cement and Concrete Composities 146, 105404. [9] J. Zhang, A. Heath, R.J. Ball, B. Chen, L. Tan, G. Li, J. Pan, T.B. Su-Cadirci, K.J.C. Paine, Piezoresistivity and piezopermittivity of cement-based sensors under quasi-static stress and changing moisture, (2024). Journal of Construction and Building Materials 425, 136052. [10] R. Gomasa, V. Talakokula, S.K.R. Jyosyula, T.J.C. Bansal, B. A review on health monitoring of concrete structures using embedded piezoelectric sensor, (2023). Journal of Construction and Building Materials 405, 133179. [11] M.K. KIM, T.U. KIM, D.J.J.C.S.i.C.M. KIM, Smart ultra-high-performance concrete under cyclic high compressive stress, (2024). Journal of Case Studies in Construction Materials, e03116. [12] W. Li, W. Dong, Y. Guo, K. Wang, S.P.J.C. Shah, Advances in multifunctional cementitious composites with conductive carbon nanomaterials for smart infrastructure, (2022). Journal of Cement and Concrete Composities 128, 104454. [13] B. Han, L. Zhang, S. Sun, X. Yu, X. Dong, T. Wu, J.J.C.P.A.A.S. Ou, Electrostatic self-assembled carbon nanotube/nano carbon black composite fillers reinforced cement-based materials with multifunctionality, (2015). Journal of Composites Part A 79, 103-115. [14] W. Dong, W. Li, K. Wang, B. Han, D. Sheng, S.P.J.C. Shah, Investigation on physicochemical and piezoresistive properties of smart MWCNT/cementitious composite exposed to elevated temperatures, (2020). Journal of Cement and Concrete Composities 112, 103675. [15] J. Tang, W. Ma, Y. Pang, J. Fan, D. Liu, L. Zhao, S.A.J.C. Sheikh, Uniaxial compression performance and stress – strain constitutive model of the aluminate cement-based UHPC after elevated temperature, (2021). Journal of Construction and Building Materials 309, 125173. [16] W. Khaliq, H.A.J.C. Khan, Elevated temperature material properties of calcium aluminate cement concrete, (2015). ournal of Construction and Building Materials 94, 475-487. [17] H. Kim, H. Son, H.-K.J.F.C. Lee, Review on recent advances in securing the long-term durability of calcium aluminate cement (CAC)-based systems, (2021). Journal of Composities and Structures 3(3), 035002. [18] R.D. Lute, Durability of calcium-aluminate based binders for rapid repair applications, 2016.