A water permeability model of nano-reinforced cement pastes based on general effective media theory and multifractals
Author Affiliations
Published Online: December 15, 2021
Open access content
Subscribed content
Free content
Trial content
| REFERENCES |
|---|
| Amnadnua K, Tangchirapat W and Jaturapitakkul C (2013) Strength, water permeability, and heat evolution of high strength concrete made from the mixture of calcium carbide residue and fly ash. Materials & Design 51: 894–901. Crossref, Google Scholar | |
| Amran YM, Farzadnia N and Ali AA (2015) Properties and applications of foamed concrete; a review. Construction and Building Materials 101(1): 990–1005. Crossref, Google Scholar | |
| Bear J (2013) Dynamics of Fluids in Porous Media. Dover Publications, New York, NY, USA. Google Scholar | |
| Bentur A and Mindess S (2006) Fibre Reinforced Cementitious Composites. CRC Press, Boca Raton, FL, USA. Crossref, Google Scholar | |
| Bentz DP and Garboczi EJ (1991) Percolation of phases in a three-dimensional cement paste microstructural model. Cement and Concrete Research 21(2–3): 325–344. Crossref, Google Scholar | |
| Bentz DP, Garboczi EJ and Martys NS (1996) Application of digital-image-based models to microstructure, transport properties, and degradation of cement-based materials. In The Modelling of Microstructure and its Potential for Studying Transport Properties and Durability (Jennings H, Kropp J and Scrivener K (eds)). Springer, New York, NY, USA, pp. 167–185. Crossref, Google Scholar | |
| Blinc R, Lahajnar G, Žumer S and Pintar MM (1988) NMR Study of the time evolution of the fractal geometry of cement gels. Physical Review B 38(4): 2873. Crossref, Google Scholar | |
| Brandt AM (2008) Fibre reinforced cement-based (FRC) composites after over 40 years of development in building and civil engineering. Composite Structures 86(1-3): 3–9. Crossref, Google Scholar | |
| Chen J, Kou SC and Poon CS (2012) Hydration and properties of nano-TiO2 blended cement composites. Cement & Concrete Composites 34(5): 642–649. Crossref, Google Scholar | |
| Chen S, Collins FG, MacLeod AJN et al. (2011) Carbon nanotube–cement composites: a retrospect. The IES Journal Part A: Civil & Structural Engineering 4(4): 254–265. Crossref, Google Scholar | |
| Chen X and Wu S (2013) Influence of water-to-cement ratio and curing period on pore structure of cement mortar. Construction and Building Materials 38: 804–812. Crossref, Google Scholar | |
| Chia KS and Zhang MH (2002) Water permeability and chloride penetrability of high-strength lightweight aggregate concrete. Cement and Concrete Research 32(4): 639–645. Crossref, Google Scholar | |
| Costa A (2006) Permeability–porosity relationship: a reexamination of the Kozeny–Carman equation based on a fractal pore–space geometry assumption. Geophysical Research Letters 33(2), https://doi.org/10.1029/2005GL025134. Crossref, Google Scholar | |
| Cui L and Cahyadi JH (2001) Permeability and pore structure of OPC paste. Cement and Concrete Research 31(2): 277–282. Crossref, Google Scholar | |
| Danoglidis PA, Konsta-Gdoutos MS, Gdoutos EE and Shah SP (2016) Strength, energy absorption capability and self-sensing properties of multifunctional carbon nanotube reinforced mortars. Construction and Building Materials 120: 265–274. Crossref, Google Scholar | |
| El-Dieb A and Hooton R (1994) Evaluation of the Katz-Thompson model for estimating the water permeability of cement-based materials from mercury intrusion porosimetry data. Cement and Concrete Research 24(3): 443–455. Crossref, Google Scholar | |
| Fukuda D, Nara Y, Kobayashi Y et al. (2012) Investigation of self-sealing in high-strength and ultra-low-permeability concrete in water using micro-focus X-ray CT. Cement and Concrete Research 42(11): 1494–1500. Crossref, Google Scholar | |
| Gao Y, Jing H and Zhou Z (2019a) Fractal analysis of pore structures in graphene oxide-carbon nanotube based cementitious pastes under different ultrasonication. Nanotechnology Reviews 8(1): 107–115. Crossref, Google Scholar | |
| Gao Y, Jing H, Zhou Z et al. (2019b) Reinforced impermeability of cementitious composites using graphene oxide-carbon nanotube hybrid under different water-to-cement ratios. Construction and Building Materials 222: 610–621. Crossref, Google Scholar | |
| Gao Y, Jing HW, Chen SJ et al. (2019c) Influence of ultrasonication on the dispersion and enhancing effect of graphene oxide–carbon nanotube hybrid nanoreinforcement in cementitious composite. Composites Part B: Engineering 164: 45–53. Crossref, Google Scholar | |
| Gao Y, Jing H, Zhou Z et al. (2020) Graphene oxide-assisted multi-walled carbon nanotube reinforcement of the transport properties in cementitious composites. Journal of Materials Science 55(2): 603–618. Crossref, Google Scholar | |
| Hansen J and Skjeltorp A (1988) Fractal pore space and rock permeability implications. Physical Review B 38(4): 2635. Crossref, Google Scholar | |
| Horne MK (1981) Sickle cell anemia as a rheologic disease. The American Journal of Medicine 70(2): 288–298. Crossref, Google Scholar | |
| Hughes D (1985) Pore structure and permeability of hardened cement paste. Magazine of Concrete Research 37(133): 227–233, https://doi.org/10.1680/macr.1985.37.133.227. Link, Google Scholar | |
| Hunt AG and Gee GW (2002) Application of critical path analysis to fractal porous media: comparison with examples from the Hanford site. Advances in Water Resources 25(2): 129–146. Crossref, Google Scholar | |
| Jacquin CG and Adler P (1987) Fractal porous media II: geometry of porous geological structures. Transport in Porous Media 2(6): 571–596. Google Scholar | |
| Jennings HM, Thomas JJ, Gevrenov JS, Constantinides G and Ulm FJ (2007) A multi-technique investigation of the nanoporosity of cement paste. Cement and Concrete Research 37(3): 329–336. Crossref, Google Scholar | |
| Jin S, Zhang J and Han S (2017) Fractal analysis of relation between strength and pore structure of hardened mortar. Construction and Building Materials 135: 1–7. Crossref, Google Scholar | |
| Jo BW, Kim CH, Tae GH and Park JB (2007) Characteristics of cement mortar with nano-SiO2 particles. Construction and Building Materials 21(6): 1351–1355. Crossref, Google Scholar | |
| Katz AJ and Thompson A (1985) Fractal sandstone pores: implications for conductivity and pore formation. Physical Review Letters 54(12): 1325. Crossref, Google Scholar | |
| Katz A and Thompson A (1986) Quantitative prediction of permeability in porous rock. Physical Review B 34(11): 8179. Crossref, Google Scholar | |
| Khalaj G, Hassani SES and Khezrloo A (2014) Split tensile strength of OPC-based geopolymers: application of DOE method in evaluating the effect of production parameters and their optimum condition. Ceramics International 40(7): 10945–10952. Crossref, Google Scholar | |
| Konsta-Gdoutos MS, Metaxa ZS and Shah SP (2010) Highly dispersed carbon nanotube reinforced cement based materials. Cement and Concrete Research 40(7): 1052–1059. Crossref, Google Scholar | |
| Li GY, Wang PM and Zhao X (2005) Mechanical behavior and microstructure of cement composites incorporating surface-treated multi-walled carbon nanotubes. Carbon 43(6): 1239–1245. Crossref, Google Scholar | |
| Li L, Jing H, Gao Y et al. (2020) Influence of methylcellulose on the impermeability properties of carbon nanotube-based cement pastes at different water-to-cement ratios. Construction and Building Materials 244: 118403. Crossref, Google Scholar | |
| Lindgreen H, Geiker M, Krøyer H, Springer N and Skibsted J (2008) Microstructure engineering of Portland cement pastes and mortars through addition of ultrafine layer silicates. Cement & Concrete Composites 30(8): 686–699. Crossref, Google Scholar | |
| Liu R, Xiao H, Li H et al. (2018) Effects of nano-SiO2 on the permeability-related properties of cement-based composites with different water/cement ratios. Journal of Materials Science 53(7): 4974–4986. Crossref, Google Scholar | |
| Lv S, Ma Y, Qiu C et al. (2013) Effect of graphene oxide nanosheets of microstructure and mechanical properties of cement composites. Construction and Building Materials 49: 121–127. Crossref, Google Scholar | |
| Ma H (2014) Mercury intrusion porosimetry in concrete technology: tips in measurement, pore structure parameter acquisition and application. Journal of Porous Materials 21(2): 207–215. Crossref, Google Scholar | |
| Mahasenan N, Smith S and Humphreys K (2003) The cement industry and global climate change: current and potential future cement industry CO2 emissions. In Proceedings of the 6th International Conference on Greenhouse Gas Control Technologies (Gale J and Kaya Y (ed)). Elsevier, pp. 995–1000. Crossref, Google Scholar | |
| Makar JM and Chan GW (2009) Growth of cement hydration products on single-walled carbon nanotubes. Journal of the American Ceramic Society 92(6): 1303–1310. Crossref, Google Scholar | |
| Mandelbrot BB (1983) The Fractal Geometry of Nature. WH Freeman, New York, NY, USA. Crossref, Google Scholar | |
| McLachlan D (1986) A new interpretation of percolation conductivity results with large critical regimes. Solid State Communications 60(10): 821–825. Crossref, Google Scholar | |
| McLachlan D (1987) An equation for the conductivity of binary mixtures with anisotropic grain structures. Journal of Physics C: Solid State Physics 20(7): 865. Crossref, Google Scholar | |
| McLachlan DS, Blaszkiewicz M and Newnham RE (1990) Electrical resistivity of composites. Journal of the American Ceramic Society 73(8): 2187–2203. Crossref, Google Scholar | |
| Moon HY, Kim HS and Choi DS (2006) Relationship between average pore diameter and chloride diffusivity in various concretes. Construction and Building Materials 20(9): 725–732. Crossref, Google Scholar | |
| Padmarajaiah S and Ramaswamy A (2002) A finite element assessment of flexural strength of prestressed concrete beams with fiber reinforcement. Cement & Concrete Composites 24(2): 229–241. Crossref, Google Scholar | |
| Pan Z, Sanjayan JG and Rangan BV (2011) Fracture properties of geopolymer paste and concrete. Magazine of Concrete Research 63(10): 763–771, https://doi.org/10.1680/macr.2011.63.10.763. Link, Google Scholar | |
| Pearson D and Allen A (1985) A study of ultrafine porosity in hydrated cements using small angle neutron scattering. Journal of Materials Science 20(1): 303–315. Crossref, Google Scholar | |
| Powers TC (1958) Structure and physical properties of hardened Portland cement paste. Journal of the American Ceramic Society 41(1): 1–6. Crossref, Google Scholar | |
| Romualdi JP and Mandel JA (1964) Tensile strength of concrete affected by uniformly distributed and closely spaced short lengths of wire reinforcement. ACI Journal Proceedings 61(6): 657–672. Google Scholar | |
| SAC (Standardization Administration of the People's Republic of China) (2007) GB 175-2007: Common Portland cement. Chinese Standard Publishing, Beijing, China. Google Scholar | |
| Sahimi M (1993) Flow phenomena in rocks: from continuum models to fractals, percolation, cellular automata, and simulated annealing. Reviews of Modern Physics 65(4): 1393. Crossref, Google Scholar | |
| Saucier A (1992) Effective permeability of multifractal porous media. Physica A: Statistical Mechanics and its Applications 183(4): 381–397. Crossref, Google Scholar | |
| Shaikh FUA and Supit SW (2015) Chloride induced corrosion durability of high volume fly ash concretes containing nano particles. Construction and Building Materials 99: 208–225. Crossref, Google Scholar | |
| Snoeck D, Velasco L, Mignon A et al. (2014) The influence of different drying techniques on the water sorption properties of cement-based materials. Cement and Concrete Research 64: 54–62. Crossref, Google Scholar | |
| Song HW, Pack SW, Nam SH, Jang JC and Saraswathy V (2010) Estimation of the permeability of silica fume cement concrete. Construction and Building Materials 24(3): 315–321. Crossref, Google Scholar | |
| Stanley HE and Meakin P (1988) Multifractal phenomena in physics and chemistry. Nature 335(6189): 405–409. Crossref, Google Scholar | |
| Tan XH, Liu JY, Li XP, Zhang LH and Cai J (2015) A simulation method for permeability of porous media based on multiple fractal model. International Journal of Engineering Science 95: 76–84. Crossref, Google Scholar | |
| Wang Y and Diamond S (2001) A fractal study of the fracture surfaces of cement pastes and mortars using a stereoscopic SEM method. Cement and Concrete Research 31(10): 1385–1392. Crossref, Google Scholar | |
| Wee T, Suryavanshi AK and Tin S (2000) Evaluation of rapid chloride permeability test (RCPT) results for concrete containing mineral admixtures. Materials Journal 97(2): 221–232. Google Scholar | |
| Wu T, Pan Z, Connell LD et al. (2020) Gas breakthrough pressure of tight rocks: a review of experimental methods and data. Journal of Natural Gas Science and Engineering 103408(81), https://doi.org/10.1016/j.jngse.2020.103408. Google Scholar | |
| Ye G (2005) Percolation of capillary pores in hardening cement pastes. Cement and Concrete Research 35(1): 167–176. Crossref, Google Scholar | |
| Yu R, Spiesz P and Brouwers H (2014) Mix design and properties assessment of ultra-high performance fibre reinforced concrete (UHPFRC). Cement and Concrete Research 56: 29–39. Crossref, Google Scholar | |
| Zhang B and Li S (1995) Determination of the surface fractal dimension for porous media by mercury porosimetry. Industrial & Engineering Chemistry Research 34(4): 1383–1386. Crossref, Google Scholar | |
| Zhang MH and Li H (2011) Pore structure and chloride permeability of concrete containing nano-particles for pavement. Construction and Building Materials 25(2): 608–616. Crossref, Google Scholar | |
| Zhutovsky S and Kovler K (2012) Effect of internal curing on durability-related properties of high performance concrete. Cement and Concrete Research 42(1): 20–26. Crossref, Google Scholar | |
| Zou B, Chen SJ, Korayem AH et al. (2015) Effect of ultrasonication energy on engineering properties of carbon nanotube reinforced cement pastes. Carbon 85: 212–220. Crossref, Google Scholar |
