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Journal of the Korea Concrete Institute

J Korea Inst. Struct. Maint. Insp.
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  • Korea Citation Index (KCI)

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  3. 2022-12 (Vol.26 No.6)
  4. 10.11112/jksmi.2022.26.6.120
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References

1 
Amor, F., Baudys, M., Racova, Z., Scheinherrova, L., Ingrisova, L., Hajek, P. (2022), Contribution of TiO$_{2}$ and ZnO nanoparticles to the hydration of Portland cement and photocatalytic properties of High Performance Concrete, Case Studies in Construction Materials, 16, e00965.DOI
2 
Ballari, M. M., and Brouwers, H., (2013), Full scale demonstration of air-purifying pavement, Journal of Hazardous Materials, 254, 406-414.DOI
3 
Cassar, L. (2004), Photocatalysis of cementitious materials: Clean buildings and clean air, MRS Bulletin 29(5), 328-331.DOI
4 
Cárdenas, C., Tobón, J. I., García, C., and Vila, J. (2012), Functionalized building materials: Photocatalytic abatement of NOx by cement pastes blended with TiO$_{2}$ nanoparticles, Construction and Building Materials, 36, 820-825.DOI
5 
Chen, C., Tang, B., Cao, X., Gu, Fan., and Huang, Wei. (2021), Enhanced photocatalytic decomposition of NO on portland cement concrete pavement using nano-TiO$_{2}$ suspension, Construction and Building Materials, 275, 122-135.DOI
6 
Chen, R., Zhang, T., Guo, Y., Wang, J., Wei, J., and Yu, Q. (2021), Recent advances in simultaneous removal of SO2 and NOx from exhaust gases: Removal process, mechanism and kinetics, Chemical Engineering Journal, 420, 127588.DOI
7 
Choi, J., Ki, T.-K., Cha, W.-H., and Han, M.-C. (2021), Effect of fineness of cement on the NOx removal performance of photocatalytic cement paste, Journal of the Architectural Institute of Korea, 37(8), 213-220.DOI
8 
Dylla, H., Hassan, M. M., Mohammad, L. N., Rupnow, T., and Wright, E. (2010), Evaluation of environmental effectiveness of titanium dioxide photocatalyst coating for concrete pavement, Transportation Research Record, 2164(1), 46-51.DOI
9 
Folli, A., Pade, C., Hansen, T. B., De Marco, T., and Macphee, D. E. (2012), TiO$_{2}$ photocatalysis in cementitious systems: Insights into self-cleaning and depollution chemistry, Cement and Concrete Research, 42(3), 539-548.DOI
10 
Gao, X., Liu, S., Zhang, Y., Luo, Z., Ni, M., and Cen, K. (2011), Adsorption and reduction of NO$_{2}$ over activated carbon at low temperature, Fuel Processing Technology, 92(1), 139-146.DOI
11 
Guerrini, G. L. (2012), Photocatalytic performances in a city tunnel in Rome: NOx monitoring results, Construction and Building Materials, 27(1), 165-175.DOI
12 
Guo, G., Hu, Y., Jiang, S., and Wei, C. (2012), Photocatalytic oxidation of NOx over TiO$_{2}$/HZSM-5 catalysts in the presence of water vapor: Effect of hydrophobicity of zeolites, Journal of Hazardous Materials, 223-224, 39-45.DOI
13 
Guo, M. -Z. Chen, J., and Poon, M. X. W. S. (2018), Pathways of conversion of nitrogen oxides by Nano TiO$_{2}$ incorporated in cement-based materials, Building and Environment, 144, 412-418.DOI
14 
Hashimoto, K., Irie, H., and Fujishima, A. (2005), TiO$_{2}$ Photocatalysis: A historical overview and future prospects, Japanese Journal of Applied Physics, 44(12), 8269-8285.URL
15 
Horgnies, M., Dubois-Brugger, I., and Gartner, E. M. (2012), NOx De-pollution by Hardened Concrete and the Influence of Activated Charcoal Additions. Cement and Concrete Research 42(10), 1348-1355.DOI
16 
I.O.f. Standardization, Fine ceramics (advanced ceramics, advanced technical ceramics) — Test method for air-purification performance of semiconducting photocatalytic materials — Part 1: Removal of nitric oxide, (2007), ISO, Geneva.URL
17 
Kleffmann, J., Becker, K. H., Lackhoff, M., and Wiesen, P. (1999), Heterogeneous conversion of NO$_{2}$ on carbonaceous surfaces, Physical Chemistry Chemical Physics, 1(24), 5443-5450.DOI
18 
Krou, N. J., Batonneau-Gener, I., Belin, T., Mignard, S., Horgnies, M., and Dubois-Brugger, I. (2013), Mechanisms of NOx entrapment into hydrated cement paste containing activated carbon — influences of the temperature and carbonation, Cement and Concrete Research, 53 , 51-58.DOI
19 
Lee, B. Y. (2018), Nitrogen oxides adsorbing capacity of high carbon fly ash containing cementitious materials, Journal of the Architectural Institute of Korea Structure & Construction, 34(3), 37-42.DOI
20 
Lee, B. Y., Jayapalan, A. R., Bergin, M. H., and Kurtis, K. E. (2014), Photocatalytic cement exposed to nitrogen oxides: Effect of oxidation and binding. Cement and Concrete Research, 60, 30-36.DOI
21 
Lee, J., and Choi, Y. C. (2020), Pore structure characteristics of foam composite with active carbon, Materials, 13(18), 4038.DOI
22 
Leng, Z., and Yu, H. (2015), Novel method of coating titanium dioxide on to asphalt mixture based on the breath figure process for air-purifying purpose, Journal of Materials in Civil Engineering, 28(5), 04015188.DOI
23 
Luna, M., Delgado, J. J., Romero, I., Montini, T., Almoraima Gil, M. L., Martinez-Lopez, J., Fornasiero, P., and Mosquera, M. J. (2022), Photocatalytic TiO$_{2}$ nanosheets-SiO2 coatings on concrete and limestone: An enhancement of de-polluting and self-cleaning properties by nanoparticle design, Construction and Building Materials, 338, 127349.DOI
24 
Lu, Z., Chen, G., Hao, W., Sun, G., and Li, Z. (2015), Mechanism of UV-assisted TiO$_{2}$/reduced graphene oxide composites with variable photo degradation of methylorange, RSC Advances 5(89), 72916-72922.DOI
25 
Lu, Z., Wang, Q., Yin, R., Chen, B., and Li, Z. (2016), A novel TiO$_{2}$/foam cement composite with enhanced photo degradation of methyl blue, Construction and Building Materials, 129, 159-162.DOI
26 
Seo, D., and Yun, T. S. (2017), NOx removal rate of photocatalytic cementitious materials with TiO$_{2}$ in wet condition, Building and Environment, 112, 233-240.DOI
27 
Faisal, S., and Patra, A. K., (2022), Investigation on photocatalytic and structural characteristics of normal concrete using TiO$_{2}$ at ambient temperature, Materials Today: Proceedings, 68(1), 164-173.DOI
28 
Yu, Q., and Brouwers, H. J. H. (2009), Indoor air purification using heterogeneous photocatalytic oxidation. Part I: Experimental study, Applied Catalysis B Environmental, 92(3-4), 454-461.DOI
29 
Yu, K. -P., Lee, G. W. M., Huang, W. -M., Wu, C., and Yang, S. (2006), The correlation between photocatalytic oxidation performance and chemical/physical properties of indoor volatile organic compounds, Atmospheric Environment, 40(2), 375-385.DOI