[
1. Li L, Shi L, Wang Q, Liu Y, Dong J, Zhang H & Zhang G: “A review on the recovery of fire-damaged concrete with post-fire-curing”. Construction and Building Materials, Vol. 237, 2020, pp. 117564.
]Search in Google Scholar
[
2. Husem M.: “The effects of high temperature on compressive and flexural strengths of ordinary and high-performance concrete”. Fire Safety Journal, Vol. 41, No. 2, pp. 155-163.
]Search in Google Scholar
[
3. Mostafaei H, Vecchio F J & Bénichou N: “Seismic resistance of fire-damaged reinforced concrete columns”. Proceedings, ATC and SEI Conference on Improving the Seismic Performance of Existing Buildings and Other Structures, San Francisco, California, USA. Dec 2009, Vol. 2, pp. 1396-1407.
]Search in Google Scholar
[
4. Yaqub M, Bailey C G, Nedwell P, Khan Q U Z & Javed I: “Strength and stiffness of post-heated columns repaired with ferrocement and fibre reinforced polymer jackets”. Composites Part B: Engineering, Vol. 44, No. 1, 2013, pp. 200-211.
]Search in Google Scholar
[
5. Noman M, Yaqub M, Abid M, Musarat M A, Vatin N I & Usman M: “Effects of low-cost repair techniques on restoration of mechanical properties of fire-damaged concrete”. Frontiers in Materials, Vol. 8, 2022, pp. 1-14.
]Search in Google Scholar
[
6. Zhang W, Zheng Q, Ashour A & Han B: “Self-healing cement concrete composites for resilient infrastructures: A review”. Composites Part B: Engineering, Vol. 189, 2020, pp. 107892.
]Search in Google Scholar
[
7. Nishiwaki T, Koda M, Yamada M, Mihashi H & Kikuta T: “Experimental study on self-healing capability of FRCC using different types of synthetic fibers”. Journal of Advanced Concrete Technology, Vol. 10, No. 6, 2012, pp. 195-206.
]Search in Google Scholar
[
8. Rajczakowska M, Nilsson L, Habermehl-Cwirzen K, Hedlund H & Cwirzen A:“Does a High Amount of Unhydrated Portland Cement Ensure an Effective Autogenous Self-Healing of Mortar?”. Materials, Vol. 12, No. 20, 2019, pp. 3298.
]Search in Google Scholar
[
9. Rajczakowska M, Habermehl-Cwirzen K, Hedlund H & Cwirzen A: “The effect of exposure on the autogenous self-healing of ordinary Portland cement mortars”. Materials, Vol. 12, No.23, 2019, pp. 3926.
]Search in Google Scholar
[
10. Poon C S, Azhar S, Anson M & Wong Y L: “Strength and durability recovery of fire-damaged concrete after post-fire-curing”. Cement and concrete research, Vol. 31, No. 9, 2001, pp. 1307-1318.
]Search in Google Scholar
[
11. Henry M, Suzuki M & Kato Y: “Behavior of Fire-Damaged Mortar under Variable Recuring Conditions”. ACI Materials Journal, Vol. 108, No. 3, 2011.
]Search in Google Scholar
[
12. Karahan O: “Residual compressive strength of fire-damaged mortar after post-fire-air-curing”. Fire and Materials, Vol. 35, No.8, 2011, pp. 561-567.
]Search in Google Scholar
[
13. Lin Y, Hsiao C, Yang H & Lin Y F: “The effect of post-fire-curing on strength–velocity relationship for nondestructive assessment of fire-damaged concrete strength”. Fire Safety Journal, Vol. 46, No. 4, 2011, pp. 178-185.
]Search in Google Scholar
[
14. Mendes A, Sanjayan J G & Collins F: “Effects of slag and cooling method on the progressive deterioration of concrete after exposure to elevated temperatures as in a fire event”. Materials and structures, Vol. 44, No. 3, 2011, pp.709-718.
]Search in Google Scholar
[
15. Li L, Jia P, Dong J, Shi L, Zhang G & Wang Q: “Effects of cement dosage and cooling regimes on the compressive strength of concrete after post-fire-curing from 800 C”. Construction and Building Materials, Vol. 142, 2011, pp. 208-220.
]Search in Google Scholar
[
16. Akca A H & Özyurt N: “Effects of re-curing on residual mechanical properties of concrete after high temperature exposure”. Construction and Building Materials, Vol. 159, 2018, pp. 540-552.
]Search in Google Scholar
[
17. Ming X, Cao M, Lv X, Yin H, Li L & Liu Z: “Effects of high temperature and post-fire-curing on compressive strength and microstructure of calcium carbonate whisker-fly ash-cement system”. Construction and Building Materials, Vol. 244, 2020, pp. 118333.
]Search in Google Scholar
[
18. Wang L & Aslani F: “Development of self-sensing cementitious composites incorporating CNF and hybrid CNF/CF”. Construction and Building Materials, Vol. 273, 2021, pp. 121659.
]Search in Google Scholar
[
19. Musso S, Tulliani J M, Ferro G & Tagliaferro A: “Influence of carbon nanotubes structure on the mechanical behavior of cement composites”. Composites Science and Technology, Vol. 69, No.11-12, 2009, pp. 1985-1990.
]Search in Google Scholar
[
20. Lu L, Ouyang D & Xu W: “Mechanical properties and durability of ultra high strength concrete incorporating multi-walled carbon nanotubes“. Materials, Vol. 9, No. 6, 2016, pp. 419.
]Search in Google Scholar
[
21. Xiao J, Han N, Li Y, Zhang Z & Shah S P: “Review of recent developments in cement composites reinforced with fibers and nanomaterials”. Frontiers of Structural and Civil Engineering, Vol. 15, No. 1, 2021, pp. 1-19.
]Search in Google Scholar
[
22. Yao Y & Lu H: “Mechanical properties and failure mechanism of carbon nanotube concrete at high temperatures”. Construction and Building Materials, Vol. 297, 2021, pp. 123782.
]Search in Google Scholar
[
23. Sedaghatdoost A & Behfarnia K: “Mechanical properties of Portland cement mortar containing multi-walled carbon nanotubes at elevated temperatures”. Construction and Building Materials, Vol. 176, 2018, pp. 482-489.
]Search in Google Scholar
[
24. Liu G, Zhang H, Kan D, Tang S & Chen Z: “Experimental study on physical and mechanical properties and micro mechanism of carbon nanotubes cement-based composites“. Fullerenes, Nanotubes and Carbon Nanostructures, Vol. 30, No. 12, 2022, pp. 1252-1263.
]Search in Google Scholar
[
25. Mohsen M O, Abdel-Jaber M T, Al-Nuaimi N A, Senouci A & Taha R A: “Determination of Surfactant Content for Optimum Strength of Multi-Walled Carbon Nanotube Cementitious Composites“. Sustainability, Vol. 14, No. 19, 2021, pp. 12433.
]Search in Google Scholar
[
26. Schindelin J, Arganda-Carreras I, Frise E, Kaynig V, Longair M, Pietzsch T, ... & Cardona A: “Fiji: an open-source platform for biological-image analysis”. Nature methods, Vol. 9, No. 7, 2012, pp. 676-682.
]Search in Google Scholar
[
27. Arganda-Carreras I, Kaynig V, Rueden C, Eliceiri K W, Schindelin J, Cardona A & Sebastian Seung H: “Trainable Weka Segmentation: a machine learning tool for microscopy pixel classification”. Bioinformatics, Vol. 33, No. 15, 2017, pp. 2424-2426.
]Search in Google Scholar
[
28. Szeląg M: “Fractal characterization of thermal cracking patterns and fracture zone in low-alkali cement matrix modified with microsilica”. Cement and Concrete Composites, Vol. 114, 2020, pp. 103732.
]Search in Google Scholar
[
29. Szeląg M: “Application of an automated digital image-processing method for quantitative assessment of cracking patterns in a lime cement matrix”. Sensors, Vol. 20, No. 14, 2020, pp. 3859.
]Search in Google Scholar
[
30. Reinhardt H W & Jooss M: “Permeability and self-healing of cracked concrete as a function of temperature and crack width”. Cement and concrete research, Vol. 33, No. 7, 2003, pp. 981-985.
]Search in Google Scholar
[
31. Pei Y, Agostini F & Skoczylas F: “Rehydration on heat-treated cementitious materials up to 700° C-coupled transport properties characterization”. Construction and Building Materials, Vol. 144, 2017, pp. 650-662.
]Search in Google Scholar
[
32. Ma Q, Guo R, Zhao Z, Lin Z & He K: “Mechanical properties of concrete at high temperature—A review”. Construction and Building Materials, Vol. 93, 2015, pp. 371-383.
]Search in Google Scholar
[
33. Feldman R F & Ramachandran V S: “Differentiation of interlayer and adsorbed water in hydrated Portland cement by thermal analysis”. Cement and Concrete Research, Vol. 1, No. 6, 1971, pp. 607-620.
]Search in Google Scholar
[
34. Saad M, Abo-El-Enein S A, Hanna G B & Kotkata M F: “Effect of temperature on physical and mechanical properties of concrete containing silica fume”. Cement and concrete research, Vol. 26, No. 5, 1996, pp. 669-675.
]Search in Google Scholar
[
35. Vyšvařil M, Bayer P, Chromá M & Rovnaníková P: “Physico-mechanical and microstructural properties of rehydrated blended cement pastes”. Construction and Building Materials, Vol. 54, 2014, pp. 413-420.
]Search in Google Scholar
[
36. Stephens C, Brown L & Sanchez F: “Quantification of the re-agglomeration of carbon nanofiber aqueous dispersion in cement pastes and effect on the early age flexural response”. Carbon, Vol. 107, 2016, pp. 482-500.
]Search in Google Scholar
[
37. Kuehnen R, Youssef M A & El-Fitiany S F: “Influence of Natural Fire Development on Concrete Compressive Strength”. Fire, Vol. 5, No. 2, 2022, pp. 34.
]Search in Google Scholar
[
38. Nalon G H, Ribeiro J C.L, de Araújo E N D, Pedroti L G, de Carvalho J M F, Santos R F & de Oliveira D S: “Residual mechanical properties of mortars containing carbon nanomaterials exposed to high temperatures”. Construction and Building Materials, Vol. 275, 2021, pp. 122123.
]Search in Google Scholar
[
39. D’Alessandro A, Rallini M, Ubertini F, Materazzi A L, & Kenny J M: “Investigations on scalable fabrication procedures for self-sensing carbon nanotube cement-matrix composites for SHM applications”. Cement and Concrete Composites, Vol. 65, 2016, pp. 200-213.
]Search in Google Scholar
[
40. Tamimi A, Hassan N M, Fattah K & Talachi A: “Performance of cementitious materials produced by incorporating surface treated multiwall carbon nanotubes and silica fume”. Construction and Building Materials, Vol. 114, 2016, pp. 934-945.
]Search in Google Scholar
[
41. Su X, Wang R, Li X, Araby S, Kuan H C, Naeem M & Ma J: “A comparative study of polymer nanocomposites containing multi-walled carbon nanotubes and graphene nanoplatelets”. Nano Materials Science, Vol. 4, No. 3, 2022, pp. 185-204.
]Search in Google Scholar