Study on Engineering Application and Degradation Efficiency of Nanoscaled TiO 2 Used as Photocatalytic Fog Sealing

There exists a great diﬀerence of the photocatalytic degradation eﬃciency between nanoscaled TiO 2 modiﬁed-emulsiﬁed asphalt applied as the fog sealing under the indoor and outdoor environment. Much eﬀorts have been made by many investigators to study this issue. However, most of them focus on the ideal condition, ignoring the degradation eﬃciency examination of TiO 2 in the actual engineering practice. A series of ﬁeld tests are carried out, accompanied with laboratory experiments, to analyze and consequently compare the photocatalytic degradation eﬃciency of nanoscaled TiO 2 in the indoor and outdoor conditions, respectively. Regression analysis was employed to investigate the inﬂuence factors of degradation eﬃciency, by which formula of function of factors inﬂuencing degradation eﬃciency and degradation eﬃciency deviation equation are obtained. The results show that when the degradation eﬃciency of NO 2 in the laboratory test is as high as 63%, the degradation eﬃciency aﬀected by the environmental factors is only 25% in the actual engineering practice. Based on the measurement data, detection indicators and criteria can be provided, which is of great signiﬁcance in the establishment of the construction quality control system.


Introduction
With the development of research on nanosized materials recently, their engineering applications have been widely expanded. e application of nanosized photocatalysis materials in water treatment, air purity, and other environmental protection fields has become a hot topic of social concern [1]. Among those, the photocatalysts represented by nano-TiO 2 can undergo strong redox reactions under UV radiation [2], which have been widely studied by domestic and foreign scholars for the degradation of automobile exhaust. Among those, numerous investigations on the photocatalysts represented by nano-TiO 2 adopted as the degradation of automobile exhaust have been carried out, owing to its characteristic of strong redox reactions exposed under UV radiation [3].
Du et al. [4,5] found that nanoscaled TiO 2 photocatalytic materials would be able to degrade NO X , HC, CO, and other components included in automobile exhaust. Wu et al. [6,7] proposed that the degradation efficiency of nanosized TiO 2 used as coated materials is better than doped materials. A study on the purification performance of TiO 2 modifiedemulsified asphalt used as a thin overlay was conducted by Wu and Ping [8]. e result showed that the degradation performance is positively correlated with temperature and UV irradiance. In conclusion, nano-TiO 2 , with its capacity for degrading automobile exhaust, plays an important role in improving the air quality. Most aforementioned research studies are primarily concerned on the degradation efficiency of nano-TiO 2 under an ideal condition of laboratory experiments, while rare attention has been paid to its actual application. Besides, there are few studies on the examination of TiO 2 degradation efficiency in practical construction. erefore, to capture the physical process of TiO 2 degradation and grasp a better understanding of the underlying mechanism, a series of comprehensive field tests accompanied with laboratory experiments are desired, which motivates this study. Main objectives of this paper are to comparing the degradation efficiency of atmospheric pollutants under both indoor and outdoor conditions, considering the photocatalytic process of TiO 2 and its influencing factors, revealing the rule of the photocatalytic effect with influencing factors and exploring the mechanism that causes the deviation of degradation efficiency exposed to these two aforementioned environments. ese results are undoubtedly of great significance to improve degradation efficiency and consequently beneficial to establish quality control systems in the construction.

Laboratory Experiments' Setup
According to the mechanism of photocatalytic degradation [9,10], nano-TiO 2 could degrade atmospheric pollutants under UV radiation.
e laboratory experiments were conducted to study its degradation efficiency, by which mixture proportion and optimal spraying amount of modified-emulsified asphalt applied as the fog sealing, from an indoor-environment perspective, could be determined. Meanwhile, the results of laboratory experiments could provide the fundamental basis for the field test construction.

Procedures of Laboratory Experiments.
e materials adopted in the laboratory experiments included SMA-13 asphalt mixture, Degussa nanosized P25 photocatalytic material imported from Germany, and cationic emulsified asphalt.
A specialized-manipulated closed chamber with size of 50 cm * 50 cm * 40 cm is served as the test equipment [11]. In order to obtain better observation, the chamber is made of quartz glass. An air inlet and an air outlet hole are reserved on the both sides for NO 2 gas input and emission respectively. To be more specific, the inlet hole is connected to a canister of NO 2 through a rubber tube, while the outlet hole is connected to an air pump and a MOT100-NO X NO x detector through a rubber tube. Moreover, a M60 light source box is installed outside the chamber as an ultraviolet light source, which power density of UV lamp is 300 W/m 2 . Detailed experimental device is shown in Figure 1(a), and the adopted NO x detector is represented in Figure 1 According to the Standard Test Methods of Bitumen and Bituminous Mixture for Highway Engineering (JTGE20-2019), two rutting structures with a size of 30 cm * 30 cm * 10 cm were, respectively, cut into specimens with dimensions of 15 cm long * 15 cm wide * 5 cm high to simulate asphalt pavement. Generally speaking, the catalytic reaction is divided into a surface reaction. us, prior to the introduction of the porous structure, e.g., zeolite powder and nano-CaCO 3 , into nano-TiO 2 [12,13], the exhaust should be adsorbed onto the surface of the catalyst for degradation. On the one respect, owing to the strong capacity of carrying and adsorption, zeolite powder could adsorb automobile exhaust into the pore channel, leading to the increment of the contact area between pollutants and nano-TiO 2 and the improvement of the degradation efficiency in consequence. Moreover, nano-CaCO 3 is characterized as a porous structure and possesses a great specific surface area. us, it could enhance the adhesion of modified-emulsified asphalt, as well as increase the adsorption area. In addition, Nano-CaCO 3 itself could promote the conversion process of NOx into calcium nitrate [14,15].
Nano-TiO 2 , nano-CaCO 3 , zeolite powder, and polyvinylpyrrolidone (PVP) were introduced into 100 ml emulsified asphalt, following the mixture-ratio of 1 : 1:2 : 0.04. Stirring the mixture thoroughly until the modifiedemulsified asphalt dropped TiO 2 was obtained. Extreme care is taken to ensure that the ultimate mixture for experiments is homogeneous. en, the mixture was sprayed to the surface of the aforementioned specimens where it is allowed with the volume of 0.3 kg/m 2 and 0.4 kg/m 2 , respectively, to form the fog sealing. Figure 2 shows the comparison between ordinary specimens and specimens covered with fog sealing. ese specimens were both set outside to aerate for an hour and then put into two closed boxes. Opening the light source box, the NO 2 with an initial concentration of 20 ppm was injected into the box. is test lasted for two hours. e degradation efficiency, according to equation (1) [16][17][18], could be calculated by comparing the amount of NO 2 contained in these two specimens within two hours: where Z represents the degradation efficiency of nitrogen dioxide, D 0 denotes the concentrations of nitrogen dioxide without UV illumination in the system, and D 1 denotes the concentrations of nitrogen dioxide with UV illumination in the system. e power of the UV lamp used in the laboratory is 18, and the UV band is 365 nm [19,20]. Figure 3 illustrates the degradation efficiency of NO 2 in the specimens covered with different amounts of TiO 2 . As shown in Figure 3, the NO 2 degradation efficiency is affected by lasting time and spraying volume. With the time extension of the decomposition, its degradation efficiency of NO 2 increases gradually. e degradation efficiency of NO 2 exceeds 60% for both conditions when time extended to 120 mins. e more the spraying volume of modifiedemulsified asphalt, which means the amount of catalyst per unit area is increased, the higher the degradation efficiency of exhaust. However, too much spraying amount will cause the modified-emulsified asphalt to run away. Moreover, the usage of fog sealing could be closely bonded with the old pavement and make full use of the degradation efficiency of TiO 2 . erefore, in actual engineering, it is recommended to apply the fog sealing for construction.

Research on Field Test
e asphalt pavement covered with photocatalytic fog sealing for testifying the practical degradation efficiency of TiO 2 was laid on a section of Shanda Road in Jinan. A 2 Advances in Materials Science and Engineering  e on-site actual degradation efficiency of TiO 2 in asphalt pavement would be obtained by comparing the concentration of pollutants before with that after construction at each monitoring point.

Construction Program.
To ensure the reliability of the subsequent comparison for indoor and outdoor measurements, raw materials used in the field test were consistent with the laboratory experiment, and the emulsion was prepared on site.
According to the mixture ratio of modified-emulsified asphalt examined from the laboratory test, nano-TiO 2 , nanocalcium carbonate, zeolite, and PVP-3000 were added to the water tank containing the emulsifier in sequence [19,20]. After thoroughly stirring for approximate an hour, the ultimate modified-emulsified asphalt would be used for fog sealing. Under the premise that the road surface was cleaned and the markings were well protected [21,22], the modifiedemulsified asphalt was sprayed with the volume range of 0.3 kg/m 2 to 0.5 kg/m 2 by the fog sealing truck. Figure 4 shows the construction site.

Clustering Analysis of Pollutant.
e data obtained by the preconstruction site air quality monitoring are shown in Figure 5. Figure 5 demonstrates that the concentrations of PM2.5 and PM10 experienced a similar variation trend, and other concentrations of pollutants also experienced similar variation trends.
us, R-type cluster analysis, i.e., assemble similar variables and select representative variables, is conducted for PM2.5, PM10, SO 2 , NO 2 , CO 2 , TVOC, O 3 , and so forth. Figure 6 and Table 1 give the clustering results. e similarity judgment is that two cases, whose approximations are close to one, could be seen as the same class. It is concluded that pollutants can be divided into four categories by this judgment and the above clustering results graph: PM2.5 and PM10 as a class, SO 2 , CO, and TVOC as a class, NO 2 as a class, and O 3 as a class. erefore, the seven variables are turned to four variables for analysis by dimension reduction. In order to further monitor by local environmental monitoring stations conveniently, PM2.5, SO 2 , NO 2 , and O 3 were selected as the four typical representative indicators for pollutants. Since the photocatalysts' function requires the stimulation of UV, with the consideration that 11 am to 14 am is the time of the day when UV intensity is strongest, the effect of photocatalyst on the degradation of exhaust can be exerted effectively right at that time. Besides, the data in the middle-part of the road are more stable than the intersection. erefore, only the four pollutants in the middle part of the road from 11 AM to 14 PM were analyzed in the following data processing.

Analysis of On-Site Pollutant Degradation Efficiency and Its Influencing Factors.
e monitoring results of the air pollutants after construction are shown in Figure 7, and the degradation efficiency of field pollutants is shown in Figure 8.
As illustrated in Figure 7, the quantities of atmospheric pollutants after construction underwent an overall declination tendency with occasional fluctuations.
is phenomenon is inseparable from the changes in the field environment. Figure 8 shows that the degradation efficiency of PM2.5 is as high as 83%, while that of others are about 22%-35%. According to the photocatalytic mechanism, SO 2 , NO 2 , O 3 , and such components would be degraded into nontoxic substances under UV radiation [23]. e resultants could be adsorbed on the road surface because of the adsorption of calcium carbonate and zeolite powder. Consequently, the quantity of pollutants was declined, which is one of majority sources of PM2.5 [24]. With the reduction of vehicle exhaust, the amount of PM2.5 was significantly reduced.
According to the on-site monitoring data, the degradation efficiency of atmospheric pollutants is greatly influenced by the changes in the environment. erefore, the factors affecting the degradation efficiency of TiO 2 within seven days after construction were analyzed. e corresponding on-site environmental situations and the strength division of UV are listed in Table 2. e strength division of UV can be obtained according to the UV index in the WMO (see in Table 3).
For simplicity, all environmental factors should be marked. First is the weather. Specifically speaking, sunny days, cloudy days, and light rain are labeled, respectively, from zero to two. e next factor is relative humidity. e average value of the relative humidity within seven days was reported to be 77% after construction. Herein, the relative humidity, lower than the average value, is defined as the low humidity with a mark of zero, while higher than the average value is defined as the high humidity and marked as one. Since the humidity in summer is above 70% in general and almost around 30% in the other three seasons, thus the low/ high humidity here is mainly associated with summer. e last factor is UV. When the UV is weak, it is marked as zero. By analogy, the UV intensity from the moderate level, strong, very strong, and extremely strong should be signed from one to four, respectively. e variation of NO 2 is taken as an example to analyze the measurement, and the results are shown in Figure 9. Figure 9 presents that the UV intensity, temperature, and humidity have significant effects on the catalytic decomposition efficiency of TiO 2 . e higher the humidity, the Advances in Materials Science and Engineering 5 lower the concentration of NO 2 . is phenomenon could be ascribed to the reason that the hole electron pair generated by nano-TiO 2 can adsorb large amounts of water molecules, resulting in more production of anions and free radicals, which are characterized with the strong redox ability.
Besides, the NO 2 concentration is much smaller on sunny days than on rainy days. is phenomenon is attributed to the fact that when the UV intensity is higher, nano-TiO 2 possesses a greater ability of generating hole electron pairs, and thus, the degradation efficiency of TiO 2 is higher [25].   erefore, in the routine application of photocatalytic fog sealing, much artificial measurements should be manipulated to compensate the lack of ultraviolet and low humidity. For example, hanging the UV lamps upon the head of street lights and sprinkling water regularly. Under the association with such artificial efforts, nano-TiO 2 would be stimulated to generate a large number of hole electron pairs and fully release its redox ability. As a consequence, the degradation efficiency of nano-TiO 2 could be improved.
To further study the effects of various factors on the degradation efficiency of nano-TiO 2 and verify the above conclusions, the linear regression equation of dependent variable Y on independent variable X was established. e amount of NO 2 should be treated as the dependent variable, while temperature, humidity, and UV intensity should be treated as the independent variables. erefore, Y is the amount of NO 2 , X 1 represents the weather, X 2 represents humidity, and X 3 represents UV intensity. e corresponding coefficients are listed in Table 4.
According to the correlation coefficients listed in Table 4, the multiple linear regression equation is obtained: e specific amount of pollutants and their degradation efficiency with the variation of the temperature, humidity, and UV intensity could be calculated via this formula. Also, the field environment could be adjusted through above artificial methods to meet the target value of degradation efficiency.

Comparative Analysis of Pollutant Degradation Efficiency in Two Different Environments
Equation (2) can control the degradation efficiency of pollutants in practical construction by changing the environment. However, the mixture proportion test and raw material performance test cannot be referred to in the laboratory test. erefore, it is necessary to compare and analyze the deviation of pollutant degradation efficiency in two different environments. On the one hand, it can ensure construction quality. On the other hand, the degradation efficiency of atmospheric pollutants in the laboratory test and the spraying amount of fog sealing can be determined by controlling the degradation efficiency of pollutants in the field. e results of the laboratory test and field test are shown, respectively, in Figures 3 and 8. e differences between the two cases can be obtained by comparing the monitoring results. When the spraying amount of modified-emulsified asphalt used as fog sealing is equal, the degradation efficiency of NO 2 in the laboratory test is far greater than it in the field testing. e former degradation efficiency is as high as 63.5% comparing to that of 25% under the harsh conditions in the field tests. e reason for the phenomenon is that the environment in the laboratory test is ideal, while the field test is eager to be influenced by multiple environmental factors.
us, it can be found that the degradation efficiency of atmospheric pollutants in practical applications is at least 39% of the effect in the laboratory test. Regression analysis can be used to get the degradation efficiency of pollutants in laboratory tests from the target values in the field. e spraying amount of modified-emulsified asphalt can be obtained by the degradation efficiency of pollutants in laboratory tests. e degradation efficiency of NO 2 can be taken as an example. e minimum degradation efficiency of NO 2 in the field is set as the independent variable, and the degradation efficiency in the laboratory test is the dependent variable. erefore, the practical degradation efficiency of NO 2 is X value, and the degradation efficiency of NO 2 in the ideal condition is Y value. e deviation equations of degradation efficiency under the indoor and outdoor environment were established by regression analysis. e correlation coefficients are shown in Table 5.
e equation can be obtained by regression analysis which is as follows: e degradation efficiency of NO 2 in the laboratory test is set as the independent variable, and the spraying amount of modified-emulsified asphalt is the dependent variable. erefore, the degradation efficiency of NO 2 in the laboratory test is set as the Y value, and the spraying amount of modified-emulsified asphalt is the Z value. e correlation coefficients obtained using regression analysis are shown in Table 6. e equation can be obtained as follows: According to equations (3) and (4), on the one hand, the minimum degradation efficiency of pollutants in the field test can be obtained by the spraying amount of the modifiedemulsified asphalt. On the other hand, the corresponding degradation efficiency in the laboratory test can be obtained by target values in the field test to test the mix proportioning design of modified-emulsified asphalt and raw material performance. e above formula could provide test indexes and standards for construction quality and lay the foundation for establishing an on-site construction quality control system.

Conclusions
A series of field tests are carried out, accompanied with laboratory experiments, to analyze and consequently compare the photocatalytic degradation efficiency of nanoscaled  TiO 2 in the indoor and outdoor conditions, respectively. Based on the measurement data, the following conclusions can be drawn. Firstly, laboratory experiments are carried out to determine the mixture proportion and optimal spraying amount of modified-emulsified asphalt applied as the fog sealing. Meanwhile, the results of laboratory experiments could provide the fundamental basis for the field test.
Second, in practical applications, the degradation efficiency of atmospheric pollutants is vulnerable to environmental factors such as temperature, humidity, and UV intensity. With the increment of the UV intensity and the growth of the humidness, the catalytic ability of the hole electron pairs generated by nano-TiO 2 becomes stronger, leading to the higher degradation efficiency of automobile exhaust. rough the linear regression analysis, the established regression equations is established, with the content of pollutants as the dependent variable and temperature, humidity, and UV intensity as the independent variables, thus to quantitatively study the influence of various factors on vehicle exhaust.
ird, the degradation efficiency of atmospheric pollutants in practical applications is only up to 39% of that in the laboratory test under the same spraying amount. e established degradation efficiency deviation equation based on this phenomenon could determine degradation efficiency in the laboratory test and the spraying amount of fog sealing could be obtained step by step, to satisfy the target of pollutant efficiency degradation in the field. Besides, it could examine the mix-proportion design of modified-emulsified asphalt and raw material performance for improving field construction quality.

Data Availability
e data used to support the findings of this study are included within the article.

Conflicts of Interest
e authors declare that they have no conflicts of interest.