Kumlai, S., Jitsangiam, P. & Pichayapan, P. The implications of temperature increase due to climate change for asphalt concrete performance and pavement design. KSCE J.Civ. Eng. 211222-1234 (2017).
Chindaprasirt, P. & Rattanasak, U. Characterization of porous alkali-activated fly ash composite as a solid adsorbent. Int. J. Greenhouse Gas Control 8530–35 (2019).
Chindaprasirt, P. & Rattanasak, U. Manufacture of self-cleaning fly ash/polytetrafluoroethylene material for cement mortar spray coating. J. Clean. production 264121748 (2020).
Jitsangiam, P., Nikraz, H. & Siripun, K. Construction and demolition (C&D) waste as base material for roads in Western Australia. August. Geomec. J 4457–62 (2009).
Jitsangiam, P. & Nikraz, H. Coarse bauxite residues for road building materials. Int. J. Pavement Eng. 14265-273 (2013).
Peerapong, J. et al. Concrete aggregates recycled on roads: Laboratory examination of self-cementing characteristics. J. Mater. Civil. Eng. 2704014270 (2015).
Huan, Y., Siripun, K., Jitsangiam, P. & Nikraz, H. A preliminary study of foamed bitumen stabilization for Western Australian pavements. Science. Res. Trials 52205 (2010).
Sounthararajah, A., Bui, H., Nguyen, N., Jitsangiam, P., and Kodikara, J. Early age fatigue damage assessment of cement-treated bases under repetitive heavy traffic loading. J. Mater. Civil ENGINEER. 3011058 (2018).
Chindaprasirt, P. & Rattanasak, U. Synthesis of alkali-activated porous materials for the treatment of highly acidic wastewater. J. Water Process Eng. 33101118 (2020).
Davidovits, J. Geopolymer: New Inorganic Polymer Materials. J. Therm. Anal. 371633–1656 (1991).
Davidovits, J. Geopolymer: chemistry and application. (Geopolymer Institute, Saint-Quantin 2008).
Palomo, A., Grutzeck, MW & Blanco, MT Alkali-activated fly ash: cement for the future. EMC concr. Res. 291323–1329 (1999).
Chindaprasirt, P., Jaturapitakkul, C., Chalee, W. & Rattanasak, U. Comparative study on characteristics of fly ash and bottom ash geopolymers. Waste management 29539-543 (2009).
Chindaprasirt, P., Jenjirapanya, S. & Rattanasak, U. Characterizations of FBC/PCC fly ash geopolymer composites. construction To build. Mater. 6672–78 (2014).
Chindaprasirt, P., Rattanasak, U., Vongvoradit, P. & Jenjirapanya, S. Heat treatment and utilization of Al-rich waste in high-calcium geopolymer materials. Int. J. Miner. Metall. Mater. 191157 (2012).
Cheng-Yong, H., Yun-Ming, L., Abdullah, MMAB, and Hussin, K. Variations in thermal resistance of fly ash geopolymers: foaming responses. Science. representing seven45355 (2017).
Maichin, P., Suwan, T., Jitsangiam, P., Chindaprasirt, P. & Fan, M. Effect of self-curing process on properties of natural fiber reinforced geopolymer composites. Mater. Fab. Treat. 351120-1128 (2020).
Jitsangiam, P., Suwan, T., Pimraksa, K., Sukontasukkul, P. & Chindaprasirt, P. Challenge of adopting a relatively low strength, self-cured geopolymer for road construction application: a review and a primary laboratory study. Int. J. Pavement Eng. https://doi.org/10.1080/10298436.2019.1696967 (2019).
Chindaprasirt, P., Chareerat, T. & Sirivivatnanon, V. Workability and strength of high calcium coarse fly ash geopolymer. EMC concr. Comp. 29224-229 (2007).
Suwan, T., Fan, M. & Braimah, N. Internal heat release and strength development of self-cured geopolymers under ambient curing conditions. construction To build. Mater. 114297-306 (2016).
Suwan, T. & Fan, M. Influence of OPC replacement and manufacturing procedures on the properties of self-cured geopolymer. construction To build. Mater. 73551-561 (2014).
Kuba, Z. et al. Impact of curing temperatures and alkaline activators on the compressive strength and porosity of ternary blended geopolymer mortars. Case stud. construction Mater. 914000 (2018).
Somna, K., Jaturapitakkul, C., Kajitvichyanukul, P. & Chindaprasirt, P. NaOH-activated ground fly ash geopolymer cured at room temperature. Fuel 902118-2124 (2011).
Chindaprasirt, P. & Rattanasak, U. Characterization of high calcium fly ash geopolymer mortar with hot weather curing systems for durable application. Adv. Powder technology. 282317-2324 (2017).
Chindaprasirt, P., Rattanasak, U. & Taebuanhuad, S. Role of microwave radiation in hardening fly ash geopolymer. Adv. Powder technology. 24703–707 (2013).
Hong, S. & Kim, H. Effects of microwave energy on the rapid development of compressive strength of coal ash geopolymers. Science. representing 915694 (2019).
Suwan, T., Paphawasit, B., Fan, M., Jitsangiam, P. & Chindaprasirt, P. Effect of microwave-assisted curing process on strength development and curing time of lightweight geopolymer mortar cellular. Mater. Fab. Treat. https://doi.org/10.1080/10426914.2021.1885702 (2021).
Graytee, A., Sanjayan, JG & Nazari, A. Development of high strength fly ash geopolymer in short time using microwave curing. Ceram. Int. 448216–8222 (2018).
Shee-Ween, O. et al. Cold-pressed fly ash geopolymers: effect of formulation on mechanical and morphological characteristics. J. Market. Res. 153028–3046 (2021).
Ranjbar, N., Kashefi, A., Ye, G. & Mehrali, M. Effects of heat and pressure on hot pressed geopolymer. construction To build. Mater. 231117106 (2020).
Suwan, T., Fan, M. & Braimah, N. Micro-mechanisms and compressive strength of the Geopolymer-Portland cementitious system under various curing temperatures. Mater. Chem. Phys. 180219-225 (2016).
Center of Excellence on Hazardous Substances Management. 100 kinds of industrial waste quantities (2008-2011) in Thailand. Chulalongkorn University http://recycle.dpim.go.th/wastelist/download_files/G/waste_quantity.pdf (2012).
Liu, K. et al. Induction heating performance of asphalt pavement incorporating electrically conductive and magnetically absorbent layers. construction To build. Mater. 22911058 (2019).
Phenrat, T., Thongboot, T. & Lowry, GV Electromagnetic induction of zero-valence iron (ZVI) powder and nanoscale zero-valence iron (NZVI) particles enhances the dechlorination of trichlorethylene in groundwater and contaminated soil: proof of concept. About. Science. Technology. 50872–880 (2016).
Kumar, S., Yankwa, DJN, Kumar, A. & Kumar, S. Geopolymerization behavior of the iron-rich fine fraction of brown fly ash. J. Build. Eng. 8172-178 (2016).
Davidovits, J. & Davidovits, R. Geopolymers of ferro-sialate (-Fe-O-Si-O-Al-O-). Geopolyme. Inst. 271–6 (2020).
Lemougna, PN, MacKenzie, KJD, Jameson, GNL, Rahier, H. & Chinje, MUF The role of iron in the formation of inorganic polymers (geopolymers) from volcanic ash: study by 57Fe Mössbauer spectroscopy. J. Mater. Science. 485280–5286 (2013).
Nongnuang, T. et al. Characteristics of waste iron powder as a fine filler in a high calcium fly ash geopolymer. Materials 1411580 (2021).
ASTM C618-19. Standard Specification for Coal Fly Ash and Raw or Calcined Natural Pozzolan for Use in Concrete. ASTM International (ASTM International, 2019). https://doi.org/10.1520/C0618-19.
Rattanasak, U. & Chindaprasirt, P. Influence of NaOH solution on fly ash geopolymer synthesis. Minor. Eng. 221073-1078 (2009).
Bakria, MA et al. The effect of curing temperature on the physical and chemical properties of geopolymers. Phys. Procedure 22286-291 (2011).
BS EN 196-1. Methods of testing cement. Strength determination. British Standards Institute (2016).
Jaśniok, T., Słomka-Słupik, B. & Zybura, A. Chlorinated corrosion of concrete reinforcement, immediately after its initiation. EMC Wapno Concrete 2014158–165 (2014).
Tang, SW, Yao, Y., Andrade, C. & Li, ZJ Recent durability studies on concrete structure. EMC concr. Res. 78143-154 (2015).
Zhao, Y., Yu, J., Hu, B. & Jin, W. Crack formation and rust distribution in corrosion-induced cracked concrete. Corros. Science. 55385–393 (2012).
Phenrat, T., Saleh, N., Sirk, K., Tilton, RD, and Lowry, GV Aggregation and sedimentation of aqueous dispersions of zero-valent iron at the nanoscale. About. Science. Technology. 41284-290 (2007).