LEADER 11550oam 22004933 450 001 9910746296303321 005 20231103172414.0 010 $a3-031-37596-3 035 $a(MiAaPQ)EBC30750435 035 $a(Au-PeEL)EBL30750435 035 $a(OCoLC) 1399982108 035 $a(EXLCZ)9928274166100041 100 $a20230923d2023 uy 0 101 0 $aeng 135 $aurcnu|||||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aSustainable advanced technologies for industrial pollution control $eProceedings of ATIPC 2022 /$fDebabrata Mazumder, editor 205 $a1st ed. 210 1$aCham :$cSpringer,$d2023. 210 4$dİ2023. 215 $a1 online resource (xvi, 408 pages) $cillustrations 225 1 $aSpringer Proceedings in Earth and Environmental Sciences Series 311 08$aPrint version: Mazumder, Debabrata Sustainable Advanced Technologies for Industrial Pollution Control Cham : Springer,c2023 9783031375958 327 $aIntro -- Preface -- Acknowledgement -- Contents -- Author Biography -- Part I: Water Quality Monitoring and Treatment in Industrial Area -- Water Decontamination Through Thiamethoxam Removal Using DL-Menthol/Octanoic Acid Deep Eutectic Solvent: Molecular Dynamics In... -- 1 Introduction -- 2 Simulation Methodology -- 3 Results and Discussion -- 4 Conclusion -- References -- Methyl Red Dye Abatement from Aqueous Solution Using Calcium Ferrite and Manganese Ferrite Magnetic Nanocomposite: Kinetics an... -- 1 Introduction -- 2 Materials and Methods -- 2.1 Chemicals and Reagents -- 2.2 Preparation of CF-MF-MNC -- 2.3 Adsorption Experiment on Batch Mode -- 3 Results and Discussion -- 3.1 Characterization of CF-MF-MNC -- 3.2 Effect of Solution pH -- 3.3 Effect of Sorption Time and MR Initial Concentration -- 3.4 Effect of Sorbent Dose -- 3.5 Adsorption Kinetic Study -- 3.6 Adsorption Isotherm Study -- 3.7 Regeneration Study -- 4 Conclusion -- References -- Adsorption of Fluoride onto PANI-Cl Jute Fibre: Designing a Higher-Flow-Rate and Higher-Initial-Concentration Column Reactor f... -- 1 Introduction -- 2 Materials and Methods -- 2.1 Materials and Methodology -- 2.2 Bed Depth Service Time -- 2.3 Theoretical Breakthrough Curve -- 3 Results and Discussion -- 3.1 Characterization -- 3.2 Theoretical Breakthrough Curve -- 3.3 Bed Depth Service Time -- 3.4 Desorption -- 4 Conclusion -- References -- Biosynthesis of Nano Zero Valent Iron (nZVI) Using Shorea robusta Leaf Extract and Its Application in UV-Assisted Photocatalyt... -- 1 Introduction -- 2 Materials and Methods -- 3 Results and Discussion -- 4 Conclusion -- References -- Method Development for the Detection of 2-Methylpyridine by High-Performance Liquid Chromatography -- 1 Introduction -- 2 Materials and Methods -- 2.1 Reagents Used -- 2.2 Solution Preparation -- 2.3 HPLC Analysis. 327 $a2.4 Doehlert Design -- 3 Results and Discussion -- 3.1 Doehlert Design -- 3.2 Linearity -- 3.3 Factor Effects -- 3.4 Adequacy of the Model -- 3.5 Response Surface Analysis -- 3.6 Model Validation and Repeatability -- 3.7 Detection and Quantitation Limits -- 3.8 Application for Industrial Effluent -- 4 Conclusion -- References -- Part II: Industrial Effluent Treatment, Reuse and Conservation -- Importance of Cost Functions for Biological Treatment of Wastewater -- 1 Introduction -- 2 Materials and Methods -- 2.1 Capacity Groups -- 2.2 Design Inlet Quality of Wastewater -- 2.3 Design Treated Quality of Wastewater -- 2.4 Design Parameters -- 2.5 Components of WWTPs -- 2.6 Design, Detailing and Cost Estimation -- 3 Results and Discussion -- 4 Conclusion -- Appendix I: Medium-range WWTPs with MBBR -- References -- Removal of Heavy Metals by Laterite Soil -- 1 Introduction -- 2 Materials and Methods -- 2.1 Chemicals -- 2.2 Instruments -- 2.3 Preparation and Characterization of the Adsorbent -- 2.4 Experimental Studies -- 3 Results and Discussion -- 3.1 Characterization Result of the Adsorbent -- 3.1.1 SEM Result -- 3.1.2 FTIR Result -- 3.1.3 EDX Result -- 3.2 Effect of Contact Time -- 3.3 Effect of Soil Dose -- 3.4 Effect of pH -- 3.5 Isotherm Studies -- 4 Conclusion -- References -- Removal of Methylene Blue from Wastewater by Red Sandy Soil-Based Alkali-Activated Binder -- 1 Introduction -- 2 Materials and Methodology -- 2.1 Reagents -- 2.2 Adsorbent Preparation -- 2.3 Instrumentation -- 2.4 Analytical Method -- 2.5 Experimental Studies -- 2.6 Study of Kinetics Models -- 3 Results and Discussions -- 3.1 Impact of Particle Size -- 3.2 Impact of Adsorbent Dosage -- 3.3 Kinetic Study -- 3.4 Effect of Agitation Speed -- 3.5 Study of Isotherm -- 3.6 Adsorption Thermodynamics Studies -- 4 Conclusion -- References. 327 $aAssessment and Treatment of Iron from Industrial Wastewater Using Parkia Speciosa Pod as Activated Carbon -- 1 Introduction -- 2 Materials and Methods -- 2.1 Sample Collection -- 2.2 Synthesis and Characterization of Adsorbent -- 2.3 Adsorbent Experiment -- 2.4 Adsorption Kinetics -- 2.5 Adsorption Isotherm -- 2.6 Thermodynamic Study -- 3 Results and Discussion -- 3.1 Site Assessment -- 3.2 Surface Characterization of the Adsorbent -- 3.3 Effect of pH -- 3.4 Effect of Time and Adsorption Kinetics -- 3.5 Adsorbent Dose and Adsorption Isotherms -- 3.6 Effects of Temperature -- 4 Conclusion -- References -- Activated Carbon Developed from Phumdi Biomass and Deccan Hemp for the Adsorption of Methylene Blue -- 1 Introduction -- 2 Materials and Methods -- 2.1 Collection of Raw Materials -- 2.2 Synthesis of Activated Carbon -- 2.3 Methodology -- 2.4 Batch Adsorption Studies -- 3 Results and Discussion -- 3.1 Site Assessment -- 3.2 Surface Characterization of the Adsorbent -- 3.3 Effect of pH -- 3.4 Effect of Time and Adsorption Kinetics -- 3.5 Adsorbent Dose and Adsorption Isotherms -- 4 Conclusion -- References -- An Experimental Study of Metanil Yellow Dye Remediation Using Fe-Mn Bimetal Oxide Composites -- 1 Introduction -- 2 Materials and Methods -- 2.1 Chemical Reagents and Materials Used -- 2.2 Methods -- 2.3 Synthesis of IMBO -- 3 Results and Discussion -- 3.1 Characterization of Synthesized IMBO -- 3.1.1 XRD -- 3.1.2 FESEM -- 3.1.3 VSM -- 3.1.4 FTIR -- 3.1.5 BET Surface Area -- 3.2 Impact of Various Experimental Variables on MY Adsorption -- 3.2.1 Influence of Solution pH -- 3.2.2 Impact of Adsorption Time -- 3.2.3 Impact of IMBO Dose -- 3.2.4 Impact of MY Concentration -- 3.3 Kinetic Study -- 3.4 Equilibrium Isotherm Study -- 3.5 Regeneration Study -- 4 Conclusion -- References. 327 $aOptimization of Electrocoagulation Process Parameters Using Magnesium Electrodes for Treating Pharmaceutical Wastewater Contai... -- 1 Introduction -- 2 Experimentation -- 2.1 Materials and Analysis -- 2.2 Fourier Transform Infrared Spectroscopy (FTIR) and X-Ray Diffraction (XRD) of Sludge -- 2.3 Electrocoagulation Setup -- 3 Results and Discussions -- 3.1 Impact of Current Density (CD) -- 3.2 Impact of Initial pH -- 3.3 Impact of Electrolyte Concentration -- 3.4 Impact of Pollutant Dose -- 3.5 Removal Kinetics -- 3.6 FTIR and XRD Analysis of Sludge -- 3.7 Energy Consumption -- 4 Conclusion -- References -- Optimization of Process Parameters for Biodegradation of Cresol by Mixed Bacterial Culture Using Response Surface Methodology -- 1 Introduction -- 2 Materials and Methods -- 2.1 Kinetic Study of Bacterial Growth and Cresol Removal by the Mixed Bacterial Culture in Various Substrate Concentration and... -- 2.2 Optimization of Operating Conditions by Response Surface Methodology (RSM) -- 2.3 Isolation of Pure Bacterial Colonies -- 2.4 Characterization of Pure Strains -- 3 Results and Discussion -- 3.1 Kinetic Study of Growth of Mixed Bacterial Culture (MBC) in Presence of Different Concentrations of Cresol and Under Vario... -- 3.2 Comparative Study of Maximum Specific Growth Rate (?max) of MBC in Different Concentrations of Cresol -- 3.3 Degradation Kinetics of Cresol by MBC in Different Cresol Concentrations and in Presence of Varying Modes of Agitations -- 3.4 Comparative Study of Maximum Specific Degradation Rate (qmax) of MBC in Different Concentrations of Cresol -- 3.5 Study of Optimization of Operating Conditions by Response Surface Methodology (RSM) -- 3.6 Isolation of Pure Bacterial Colonies -- 3.7 Characterization of Pure Strains -- 4 Conclusion -- References. 327 $aBiological Degradation of Cresol Containing Waste Water Using Mixed Microbial Culture in Presence of Heavy Metals -- 1 Introduction -- 2 Materials and Methods -- 3 Results and Discussion -- 3.1 Effect of Cr(VI) on Biodegradation of Cresol -- 3.2 Effect of Pb(II) on Biodegradation of Cresol -- 3.3 Effect of Cd(II) on Biodegradation of Cresol -- 3.4 Variation of Specific Growth Rate of the Culture with a Variety of Cresol and Metal Combinations -- 3.5 Determination of IC50 Value of Heavy Metals -- 3.6 Characterization and Identification of Predominant Bacteria from the Mixed Culture -- 4 Conclusion -- References -- Part III: Monitoring of Industrial Emission and Control -- Development of a Simplistic Model for the Prediction of Reactive Air Pollutants in the Atmosphere -- 1 Introduction -- 2 Materials and Methods -- 2.1 Development of Model -- 2.2 Solutions of the Model -- 3 Results and Discussion -- 4 Conclusion -- References -- Controlling Air and Metal Pollution in Industrial Area Singrauli, India: Role of Plants -- 1 Introduction -- 2 Materials and Methods -- 2.1 Study Area -- 2.2 Sampling -- 2.3 Experimental Study -- 2.3.1 Biochemical Parameter of APTI -- 2.3.2 Dust-Capturing Capacity (DCC) -- 2.3.3 Field Emission Scanning Electron Microscopy (FESEM) -- 2.3.4 Heavy Metal Analysis of Leaf and Soil Sample -- 2.3.5 Bioaccumulation Factor (BAF) -- 2.4 Quality Control -- 2.5 Statistical Analysis -- 3 Results and Discussion -- 3.1 Biochemical Parameter of APTI -- 3.2 Dust-Capturing Capacity -- 3.3 Estimation of Metals in Soil and Plants -- 4 Conclusion -- References -- Part IV: Industrial Solid Waste Management -- Enhancing the Dewatering Ability of Sludge by Locally Available Biomass -- 1 Introduction -- 2 Materials and Methods -- 2.1 Materials -- 2.2 Methodology -- 2.2.1 Preparation of MCSB-FeCl3 -- 2.2.2 Analytical Methods -- Capillary Suction Time (CST). 330 $aThis proceedings volume constitutes peer-reviewed full-length papers contributed by the Authors and tailored on various thematic areas of the 3rd International Conference on ?Advanced Technologies for Industrial Pollution Control? (ATIPC ? 2022). The areas of research covered by these papers include but are not limited to: ?Water quality monitoring and treatment in industrial area ?Industrial effluent treatment, reuse and conservation ?Monitoring of industrial emission and control ?Industrial solid waste management ?Handling and disposal of hazardous waste ?Case Studies on industrial pollution control ?Innovative technologies in industrial waste management 410 0$aSpringer proceedings in earth and environmental sciences 606 $aPollution control industry$vCongresses 615 0$aPollution control industry 676 $a354.335 701 $aMazumder$b Debabrata$01429538 712 12$aInternational Conference on Advanced Technologies for Industrial Pollution Control. 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910746296303321 996 $aSustainable Advanced Technologies for Industrial Pollution Control$93568541 997 $aUNINA