[3] HENDRYX M, LUO J H. COVID-19 prevalence and fatality rates in association with air pollution emission concentrations and emission sources［J］. Environmental Pollution, 2020, 265: 115126.

[5] GENG Z, XIN M Y, ZHU X T, et al. A new method for preparing photocatalytic cement-based materials and the investigation on properties and mechanism［J］. Journal of Building Engineering, 2021, 35: 102080.

[6] HAKKI A, YANG L, WANG F Z, et al. Photocatalytic functionalized aggregate: enhanced concrete performance in environmental remediation［J］. Buildings, 2019, 9(2): 28.

[7] MACPHEE D E, FOLLI A. Photocatalytic concretes: the interface between photocatalysis and cement chemistry［J］. Cement and Concrete Research, 2016, 85: 48-54.

[8] FOLLI A, JAKOBSEN U H, GUERRINI G L, et al. Rhodamine B discolouration on TiO2 in the cement environment: a look at fundamental aspects of the self-cleaning effect in concretes［J］. Journal of Advanced Oxidation Technologies, 2009, 12(1): 126-133.

[9] FOLLI A, PADE C, HANSEN T B, et al. TiO2 photocatalysis in cementitious systems: insights into self-cleaning and depollution chemistry［J］. Cement and Concrete Research, 2012, 42(3): 539-548.

[10] BENGTSSON N, CASTELLOTE M. Heterogeneous photocatalysis on construction materials: effect of catalyst properties on the efficiency for degrading NOx and self cleaning［J］. Materiales De Construcción, 2014, 64(314): e013.

[11] JIMENEZ-RELINQUE E, CASTELLOTE M. Influence of the inlet air in efficiency of photocatalytic devices for mineralization of VOCs in air-conditioning installations［J］. Environmental Science and Pollution Research, 2014, 21(19): 11198-11207.

[13] SERPONE N. Heterogeneous photocatalysis and prospects of TiO2-based photocatalytic DeNOxing the atmospheric environment［J］. Catalysts, 2018, 8(11): 553.

[14] CASSAR L. Photocatalysis of cementitious materials: clean buildings and clean air［J］.MRS Bulletin, 2004, 29(5): 328-331.

[15] ZHANG K L, LIU C M, HUANG F Q, et al. Study of the electronic structure and photocatalytic activity of the BiOCl photocatalyst［J］. Applied Catalysis B: Environmental, 2006, 68(3/4): 125-129.

[16] NAVA-NU＇EZ M Y, JIMENEZ-RELINQUE E, GRANDE M, et al. Photocatalytic BiOX mortars under visible light irradiation: compatibility, NOx efficiency and nitrate selectivity［J］. Catalysts, 2020, 10(2): 226.

[17] FENG P, CHANG H L, LIU X, et al. The significance of dispersion of nano-SiO2 on early age hydration of cement pastes［J］. Materials & Design, 2020, 186: 108320.

[18] GAO X Y, TANG G B, PENG W, et al. Surprise in the phosphate modification of BiOCl with oxygen vacancy: in situ construction of hierarchical Z-scheme BiOCl-OV-BiPO4 photocatalyst for the degradation of carbamazepine［J］. Chemical Engineering Journal, 2019, 360: 1320-1329.

[19] WANG D, HOU P K, YANG P, et al. BiOBr@SiO2 flower-like nanospheres chemically-bonded on cement-based materials for photocatalysis［J］. Applied Surface Science, 2018, 430: 539-548.

[20] YUE P, ZHANG G Q, CAO X Z, et al. In situ synthesis of Z-scheme BiPO4/BiOCl0.9I0.1 heterostructure with multiple vacancies and valence for efficient photocatalytic degradation of organic pollutant［J］. Separation and Purification Technology, 2019, 213: 34-44.

[21] LIU Y Z, XU J, WANG L Q, et al. Three-dimensional BiOI/BiOX (X=Cl or Br) nanohybrids for enhanced visible-light photocatalytic activity［J］. Nanomaterials (Basel, Switzerland), 2017, 7(3): 64.

[22] JIMENEZ-RELINQUE E, RODRIGUEZ-GARCIA J R, CASTILLO A, et al. Characteristics and efficiency of photocatalytic cementitious materials: type of binder, roughness and microstructure［J］. Cement and Concrete Research, 2015, 71: 124-131.