Ahamed, A., Liang, L., Chan, W. P., Tan, P. C. K., Yip, N. T. X., Bobacka, J. & Lisak, G. (2021). In situ catalytic reforming of plastic pyrolysis vapors using MSW incineration ashes. Environmental Pollution, 276, 116681.
Atamaleki, A., Zarandi, S. M., Massoudinejad, M., Esrafili, A.andKhaneghah, A. M. (2022). Emission of BTEX compounds from the frying process: Quantification, environmental effects,andprobabilistic health risk assessment. Environmental Research, 204, 112295.
Cao, Y., Dhahad, H. A., Farouk, N., Xia, W. F., Rad, H. N., Ghasemi, A. & Shayesteh, A. A. (2021). Multi-objective bat optimization for a biomass gasifier integrated energy system based on 4E analyses. Applied Thermal Engineering, 196, 117339.
Davidson, C. J., Hannigan, J. H.andBowen, S. E. (2020). Effects of inhaled combined Benzene, Toluene, Ethylbenzene,andXylenes (BTEX): Toward an environmental exposure model. Environmental toxicologyandpharmacology, 103518.
Ghasemi, A., Shayesteh, A. A., Doustgani, A.andPazoki, M. (2021). Thermodynamic assessmentandoptimization of a novel trigeneration energy system based on solar energyandMSW gasification using energyandexergy concept. Journal of Thermal Engineering, 7(1), 349-366.
Guo, Y., Wen, M., Li, G.andAn, T. (2021). Recent advances in VOC elimination by catalytic oxidation technology onto various nanoparticles catalysts: a critical review. Applied Catalysis B: Environmental, 281, 119447.
Hosseinzadeh, A., Najafpoor, A. A., Jafari, A. J., Jazani, R. K., Baziar, M., Bargozin, H.andPiranloo, F. G. (2018). Application of response surface methodologyandartificial neural network modeling to assess non-thermal plasma efficiency in simultaneous removal of BTEX from waste gases: Effect of operating parametersandprediction performance. Process SafetyandEnvironmental Protection, 119, 261-270.
Hsieh, P. Y., Shearston, J. A.andHilpert, M. (2021). Benzene emissions from gas station clusters: a new framework for estimating lifetime cancer risk. Journal of Environmental Health ScienceandEngineering, 19(1), 273-283.
Ibrahim, S., Jagannath, A.andRaj, A. (2020). Aromatics oxidation in the furnace of sulfur recovery units: Model developmentandoptimization. Journal of Natural Gas ScienceandEngineering, 83, 103581.
Kim, Y., Rhee, G., Heo, S., Nam, K., Li, Q.andYoo, C. (2020). Human Health Risk, EnvironmentalandEconomic Assessment Based on Multimedia Fugacity Model for Determination of Best Available Technology (BAT) for VOC Reduction in Industrial Complex. Korean Chemical Engineering Research, 58(3), 325-345.
Lando, A. T., Djamaludin, I., Arifin, A. N., Oktorina, N., Danah, R.andSulistyowati, M. F. (2020, June). The Effectiveness of Incinerator at the Integrated Waste Treatment Plant in the Campus of Engineering Faculty-Hasanuddin University. In IOP Conference Series: Materials ScienceandEngineering (Vol. 875, No. 1, p. 012017). IOP Publishing.
Lhuissier, M., Couvert, A., Dabert, P., Amrane, A., Kane, A., Audic, J. L.andDumont, E. (2022). Removal of a Mixture of Seven Volatile Organic Compounds (VOCs) Using an Industrial Pilot-Scale Process Combining Absorption in Silicone OilandBiological Regeneration in a Two-Phase Partitioning Bioreactor (TPPB). Energies, 15(13), 4576.
Liang, C., Huang, C. F.andChen, Y. J. (2008). Potential for activated persulfate degradation of BTEX contamination. water research, 42(15), 4091-4100.
Manna, M.andSen, S. (2022). Advanced oxidation process: a sustainable technology for treating refractory organic compounds present in industrial wastewater. Environmental ScienceandPollution Research, 1-29.
Mohajeri, L., Shayesteh, A. A., Zahed, M. A.andPakravan, M. (2022). FateandEffect of Micro Plastic in the Aquatic Environment. Journal of Oceanography, 12(48), 53-65.
Mužina, K., Kurajica, S., Guggenberger, P., Duplančić, M.andDražić, G. (2022). Catalytic activityandproperties of copper-doped ceria nanocatalyst for VOCs oxidation. Journal of Materials Research, 1-12.
Najafpoor, A. A., Jafari, A. J., Hosseinzadeh, A., Jazani, R. K.andBargozin, H. (2018). Optimization of non-thermal plasma efficiency in the simultaneous elimination of benzene, toluene, ethyl-benzene,andxylene from polluted airstreams using response surface methodology. Environmental ScienceandPollution Research, 25(1), 233-241.
Ojimelukwe, A. E., Nafagha-Lawal, M. O., Lelei, K. E., Uche, A. O., Kika, E. P., Igbiri, S.,& Sikoki, F. D. (2021). Petroleum hydrocarbon pollution in the Niger Delta: human health risk assessment of BTEX in biota. ToxicologyandEnvironmental Health Sciences, 13(1), 65-72.
Olivares, C. I., Yi, S., Cook, E. K., Choi, Y. J., Montagnolli, R., Byrne, A. & Alvarez-Cohen, L. (2022). Aerobic BTEX biodegradation increases yield of perfluoroalkyl carboxylic acids from biotransformation of a polyfluoroalkyl surfactant, 6: 2 FtTAoS. Environmental Science: Processes & Impacts, 24(3), 439-446.
Peng, Y., Yang, Q., Wang, L., Wang, S., Li, J., Zhang, X. & Fantozzi, F. (2021). VOC emissions of coal-fired power plants in China based on life cycle assessment method. Fuel, 292, 120325.
Raazi Tabari, M. R., Sabzalipour, S., Peyghambarzadeh, S. M.andJalilzadeh Yengejeh, R. (2020). Determining the emission rates of volatile organic compoundsandmodeling their dispersion from the petroleumandchemical storage tanks of the largest oil terminal in the southwest of Iran. Journal of Advances in Environmental Health Research, 8(4), 269-280.
Shahbazi, H., Abolmaali, A. M., Alizadeh, H., Salavati, H., Zokaei, H., Zandavi, R., ... & Hosseini, V. (2021). Development of high-resolution emission inventory to study the relative contribution of a local power plant to criteria air pollutantsandGreenhouse gases. Urban Climate, 38, 100897.
Sohrabi, T., Shakiba, M., Mirzaei, F.andPourbabaee, A. A. (2022). BTEX biodegradation using Bacillus sp. in a synthetic hypoxic aquatic environment: optimization by Taguchi-based design of experiments. International Journal of Environmental ScienceandTechnology, 19(6), 5571-5578.
Soltanianzade, Z., Mirmohammadi, M.andZahed, M. A. (2023). EnergyandEnvironmental Optimization of a Bituminous Waterproofing Plant for BTEX Emission Mitigation Using IncineratorandOxidation Method. Environmental EnergyandEconomic Research, 7(2): S055.
Sorrels, J. L., Am, B., Randall, D.andHancy, C. (2017). Incineratorsandoxidizers. United States Environmental Protection Agency.
Su, C., Wei, H., Wang, Z., Ayed, H., Mouldi, A.andShayesteh, A. A. (2022). Economic accountingandhigh-tech strategy for sustainable production: A case study of methanol production from CO2 hydrogenation. International Journal of Hydrogen Energy.
Tomatis, M., Moreira, M. T., Xu, H., Deng, W., He, J.andParvez, A. M. (2019). Removal of VOCs from waste gases using various thermal oxidizers: A comparative study based on life cycle assessmentandcost analysis in China. Journal of cleaner production, 233, 808-818.
Ulutaş, K., Kaskun, S., Demir, S., Dinçer, F.andPekey, H. (2021). Assessment of H2SandBTEX concentrations in ambient air using passive sampling methodandthe health risks. Environmental MonitoringandAssessment, 193(7), 1-10.
Van der Kamp, J. (2017). Social cost-benefit analysis of air pollution control measures-Advancing environmental-economic assessment methods to evaluate industrial point emission sources. KIT Scientific Publishing.
Vellingiri, K., Choudhary, V., Kumar, S.andPhilip, L. (2022). Sorptive removal versus catalytic degradation of aqueous BTEX: A comprehensive review in the perspective of life-cycle assessment. Environmental Science: Water Research & Technology.
Wang, H., Sun, S., Nie, L., Zhang, Z., Li, W.andHao, Z. (2022). A review of whole-process control of industrial volatile organic compounds in China. Journal of Environmental Sciences.
Yu, B., Yuan, Z., Yu, Z.andXue-song, F. (2022). BTEX in the environment: An update on sources, fate, distribution, pretreatment, analysis,andremoval techniques. Chemical Engineering Journal, 134825.