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Warianty tytułu
Nanomaterial dispersion methods in a cement matrix
Języki publikacji
Abstrakty
Celem artykułu jest rozwinięcie tematu prawidłowego rozmieszczenia nanomateriału w matrycy cementowej wraz ze wskazaniem efektywnych metod dyspersji nanomateriałów.
The aim of the article is to elaborate on the proper distribution of nanomaterials in a cement matrix together with the indication of the effective methods of nanomaterials dispersion.
Wydawca
Czasopismo
Rocznik
Tom
Strony
38--42
Opis fizyczny
Bibliogr. 26 poz., fot., rys., tab.
Twórcy
- Politechnika Śląska
Bibliografia
- 1. Kostrzanowska-Siedlarz A.: Nanomodyfikacja betonu. ”Magazyn Autostrady”, 11-12/2015, s. 50-56.
- 2. Kostrzanowska-Siedlarz A.: Właściwości nanokompozytów cementowych. „Magazyn Autostrady”, 5/2017, s. 91-95.
- 3. Kostrzanowska-Siedlarz A.: Inteligentne nawierzchnie drogowe i konstrukcje z nanomateriałami. „Magazyn Autostrady”, 8-9/2017, s. 30-34.
- 4. Masłowski M.: Ocena stopnia dyspersji nanonapełniaczy w kompozytach polimerowych. Instrukcja laboratorium. Nanomateriały i Nanotechnologie polimerowe. Łódź 2013.
- 5. Horszczaruk E., Mijowska E., Cendrowski K., Mijowska S., Sikora P.: Effect of incorporation route on dispersion of mesoporous silica nanospheres in cement mortar. „Construction and Building Materials”, vol. 66, 2014, s. 418-421.
- 6. Horszczaruk E., Mijowska E., Cendrowski K., Sikora P.: Influence of the new method of nanosilica addition on the mechanical properties of cement mortars. „Cement Wapno Beton”, 5/2014, s. 308-315.
- 7. Isfahani F.T., Li W., Redaelli E.: Dispersion of multi-walled carbon nanotubes and its effects on the properties of cement composites. „Cement and Concrete Composites”, vol. 74, 2016, s.154-163.
- 8. Ludvig P., Calixto J.M., Ladeira L.O., Gaspar I.C.: Using converter dust to produce low cost cementitious composites by in situ carbon nanotube and nanofiber synthesis. „Materials”, 4/2011, s. 575-584.
- 9. Morsy M., Alsayed S., Aqel M.: Hybrid effect of carbon nanotube and nano-clay on physico-mechanical properties of cement mortar. „Construction and Building Materials”, vol. 25, 2011, s. 145-149.
- 10. Li G.Y., Wang P.M., Zhao X.: Mechanical behavior and microstructure of cement composites incorporating surface-treated multi-walled carbon nanotubes. „Carbon”, vol. 43, 2005, s.1239-1245.
- 11. Chaipanich A., Nochaiya T., Wongkeo W., Torkittikul P.: Compressive strength and microstructure of carbon nanotubes–fly ash cement composites. „Materials Science and Engineering.”, vol. 527, 2010, s. 1063-1067.
- 12. Bharj J., Singh S., Chander S., Singh R.: Experimental study on compressive strength of cement-CNT composite paste. „Indian Journal of Pure and Applied Physics”, vol. 52, 2014, s. 35-38.
- 13. 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, 2009, s. 1985-1990.
- 14. Konsta-Gdoutos M.S., Metaxa Z.S., Shah S.P.: Multi-scale mechanical and fracture characteristics and early-age strain capacity of high performance carbon nanotube/cement nanocomposites. „Cement and Concrete Composites”, vol. 32, 2010, s. 110-115.
- 15. Abu Al-Rub R.K., Ashour A.I., Tyson B.M.: On the aspect ratio effect of multiwalled carbon nanotube reinforcements on the mechanical properties of cementitious nanocomposites. „Construction and Building Materials”, vol. 35, 2012, s. 647-655.
- 16. Coppola L., Cadoni E., Forni D., Buoso A.: Mechanical characterization of cement composites reinforced with fiberglass, carbon nanotubes or glass reinforced plastic (GRP) at high strain rates. „Applied Mechanics and Materials”, vol. 82, 2011, s. 190-195.
- 17. Abu Al-Rub R.K., Tyson B.M., Yazdanbakhsh A., Grasley Z.: Mechanical properties of nanocomposite cement incorporating surface-treated and untreated carbon nanotubes and carbon nanofibers. „Journal of Nanomechanics and Micromechanics”, 2/2012, s. 1-6.
- 18. Hu Y., Luo D., Li P., Li Q., Sun G.: Fracture toughness enhancement of cement paste with multi-walled carbon nanotubes. „Constr. Build. Mater”, 70, 2014, s. 332-338.
- 19. Collins F., Lambert J., Hui Duan W.: The influences of admixtures on the dispersion workability and strength of carbon nanotube-OPC paste mixtures. „Construction and Building Materials”, vol. 34, 2012, s. 201-207.
- 20. Camacho MdC., Galao O., Baeza F.J., Zornoza E., Garces P.: Mechanical properties and durability of CNT cement composites. „Materials”, 7/2014, s. 1640-1651.
- 21. Zhou C., Li F., Hu J., Ren M.,Wei J., Yu Q.: Enhanced mechanical properties of cement paste by hybrid graphene oxide/carbon nanotubes. „Construction and Building Materials”, vol. 134, 2017, s. 336-345.
- 22. Jiang L., Gao L., Sun J.: Production of aqueous colloidal dispersions of carbon nanotubes. „Journal of Colloid and Interface Science”, 1 (260)/2003, s. 89-94.
- 23. Qiu L., Yang X., Gou X., Yang W., Ma Z., Wallace G.G. et al.: Dispersing carbon nanotubes with graphene oxide in water and synergistic effects between graphene derivatives. „Chemistry – A European Journal”, 35 (16)/2010, s. 10653-10658.
- 24. Lua Z., Hanifa A., Ningb C., Shaoa H., Yina R., Li Z.: Steric stabilization of graphene oxide in alkaline cementitious solutions: Mechanical enhancement of cement composite. „Materials & Design”, vol. 127, 2017, s. 154-161.
- 25. Baoguo H., Siqi D., Xun Y.: Intrinsic self-sensing concrete and structures: A review. „Measurement”, vol. 59, 2015, s. 110-128.
- 26. Vaisman L., Wagner H.D., Marom G.: The role of surfactants in dispersion of carbon nanotubes. „Advances in Colloid and Interface Science”, vol. 128-130, 2006, s. 37-46.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-b6ddb7ad-2659-4727-ab54-fa894c726746