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Aizpurua, J., Baumberg, J., Boltasseva, A., Christopher, P., Cortes, E., & Cronin, S. B., et al. (2019). New materials for hot electron generation: general discussion. Faraday Discussions, 214.Search in Google Scholar
Jae‐Wan Lee, Seung‐Deok Seo, & Dong‐Wan Kim. (2019). Hierarchical zn 1.67 mn 1.33 o 4 /graphene nanoaggregates as new anode material for lithium-ion batteries. International Journal of Energy Research, 43(5).Search in Google Scholar
Dekeyser, L., Verdonck, A., & De Clercq, H. (2017). Belgian craftsmanship in the interwar period: formulas and application techniques of decorative cement-based wall finishes. International journal of architectural heritage, 11(5-8), 621-635.Search in Google Scholar
Yang, P., Zhang, H., Liu, Q., Liu, J., Chen, R., & Yu, J., et al. (2019). Nano-sized architectural design of multi-activity graphene oxide (go) by chemical post-decoration for efficient uranium(Ⅵ) extraction. Journal of Hazardous Materials, 375(AUG.5), 320-329.Search in Google Scholar
A, L. J., A, V. K., A, N. D., B, M. L., & B, S. T. (2021). Ag-in-se films on flexible architectural textiles as efficient material for optoelectronics applications: a preliminary study. Thin Solid Films.Search in Google Scholar
Tomlinson, K. W., Van Langevelde, F., Ward, D., Prins, H. H. T., De Bie, S., & Vosman, B., et al. (2016). Defence against vertebrate herbivores trades off into architectural and low nutrient strategies amongst savanna fabaceae species. Oikos, 125(1), 126-136.Search in Google Scholar
Kontoleon, K. J., & Giarma, C. (2016). Dynamic thermal response of building material layers in aspect of their moisture content. Applied Energy, 170(may 15), 76-91.Search in Google Scholar
Nazarov, Y. V., Kornilova, A. A., & Tyurin, S. M. (2018). Light decoration of a city as an art interpretation of architectural basis (as exemplified by astana). Light and Engineering, 26(3), 116-123.Search in Google Scholar
Shahda, M. M., Abd Elhafeez, M. M., & El Mokadem, A. A. (2018). Camel’s nose strategy: new innovative architectural application for desert buildings. Solar Energy, 176(DEC.), 725-741.Search in Google Scholar
Yalcin, Mehmet, Ali, Tuncoku, S., & Sarp, et al. (2015). Assessment of construction techniques and material usage in. izmir rural houses. International Journal of Architectural Heritage.Search in Google Scholar
Nawar, M., Salim, H., Lusk, B., & Kiger, S. (2015). Modeling and shock tube testing of architectural glazing systems for blast resistance. Journal of Structural Engineering(141-7).Search in Google Scholar
Zhang, L., & Peng, Z. (2021). Planning and maintenance of urban architectural environmental color—a case study of xingning traditional block in nanning city. International Journal of Electrical Engineering Education, 002072092098467.Search in Google Scholar
Valente, M., Sambucci, M., Musacchi, E., Sibai, A., & Valente, M. (2020). Multi-physics analysis for rubber-cement applications in building and architectural fields: a preliminary analysis. Sustainability, 12(15), 21.Search in Google Scholar
Mahumane, G., Kumar, P., Toit, L. D., Choonara, Y. E., & Pillay, V. (2018). 3d scaffolds in neural tissue engineering: architectural challenges. Biomaterials Science, 6(11), 2812-2837.Search in Google Scholar
Yang, Y., Liu, J. C., Yang, S. G., Fang, Q., Rong, C., & Li, Z. (2021). Experimental study of the dynamic response of architectural glasses under vented explosion loads of methane–air mixtures. International Journal of Impact Engineering, 148, 103749-.Search in Google Scholar
Wilhelm, S., & Curbach, M. (2015). Review of possible mineral materials and production techniques for a building material on the moon. Structural Concrete, 15(3), 419-428.Search in Google Scholar
Liang, X., Sun, X., Lu, Q., Ren, L., & Chen, L. (2021). Voc emission inventory of architectural coatings and adhesives for new buildings in china based on investigated and measured data. Atmospheric Environment, 245(5), 118014.Search in Google Scholar
Dade-Robertson, M. (2021). Bacterial spore-based hygromorphs: a novel active material with potential for architectural applications. Sustainability, 13.Search in Google Scholar
Yan, Z., Niu, X. Y., Du, X. Q., Wang, Q. C., Wu, X. J., & Zhou, Y. N. (2018). Activating ain thin film by introducing co nanoparticles as a new anode material for thin-film lithium batteries. Rare Metals, v.37(08), 3-10.Search in Google Scholar
Ferrari, G., & Zannini, P. (2017). Vocs monitoring of new materials for ceramic tiles decoration: gc–ms analysis of emissions from common vehicles and inkjet inks during firing in laboratory. Boletin De La Sociedad Espanola De Ceramica Y Vidrio, 56(5).Search in Google Scholar
Hamrouni, A., Rebiere, J. L., Mahi, A. E., Beyaoui, M., & Haddar, M. (2022). Experimental analysis of the static and dynamic behavior of 3d printed bio-based conventional and auxetic architectural materials. International Journal of Applied Mechanics, 14(10).Search in Google Scholar
Hu, J., Chen, W., Qu, Y., & Yang, D. (2020). Safety and serviceability of membrane buildings: a critical review on architectural, material and structural performance. Engineering Structures, 210(May1), 110292.1-110292.12.Search in Google Scholar
Dong, Z., Jia, H., & Liu, M. (2018). An adaptive multiobjective genetic algorithm with fuzzy c -means for automatic data clustering. Mathematical Problems in Engineering, 2018(PT.5), 1-13.Search in Google Scholar
Deccia, C. M. A., Wiese, D. N., & Nerem, R. S. (2022). Using a multiobjective genetic algorithm to design satellite constellations for recovering earth system mass change. Remote Sensing, 14.Search in Google Scholar