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xv | |
| Preface |
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xxiii | |
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1 Application of Omics Technologies for Microbial Community Structure and Function Analysis in Contaminated Environment |
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1 | (40) |
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1 | (3) |
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1.2 Next-generation sequencing and development of omics approaches |
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4 | (18) |
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22 | (13) |
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1.4 Challenges and future prospects |
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35 | (1) |
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35 | (1) |
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36 | (3) |
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39 | (2) |
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2 Metagenomics: A Possible Solution for Uncovering the "Mystery Box" of Microbial Communities Involved in the Treatment of Wastewater |
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41 | (14) |
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41 | (1) |
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42 | (1) |
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2.3 Various tools of genomics |
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42 | (2) |
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44 | (1) |
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2.5 Genomics in bioremediation |
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44 | (1) |
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2.6 The genes in the environmental samples |
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45 | (1) |
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2.7 Role of metagenomics in wastewater treatment |
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45 | (4) |
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49 | (1) |
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49 | (1) |
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50 | (1) |
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50 | (5) |
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3 Molecular Tools for Microbial Diversity Analysis |
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55 | (12) |
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55 | (1) |
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3.2 Molecular-based approaches |
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56 | (1) |
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3.3 Polymerase chain reaction-independent techniques |
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56 | (1) |
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3.4 Nucleic acid reassociation and hybridization |
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57 | (1) |
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57 | (1) |
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3.6 Reverse sample genome probing |
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58 | (1) |
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3.7 Molecular techniques based on polymerase chain reaction methods |
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58 | (2) |
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3.8 The denaturing gradient gel electrophoresis methods |
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60 | (2) |
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3.9 Next-generation sequencing |
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62 | (1) |
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63 | (1) |
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64 | (3) |
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4 Role of Microorganisms in Performance Optimization of Wastewater Treatment Plants |
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67 | (26) |
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67 | (1) |
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4.2 Categorization of wastewater |
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68 | (1) |
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4.3 Composition of typical wastewater |
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68 | (1) |
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4.4 Brief description of processes involved in a wastewater treatment plant |
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69 | (2) |
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4.5 Mechanism of bioremediation |
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71 | (1) |
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4.6 Microbes in wastewater treatment |
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72 | (5) |
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77 | (1) |
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4.8 Wastewater bioremediation techniques |
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78 | (4) |
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4.9 Factors affecting microbial growth and bioremediation |
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82 | (3) |
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4.10 Processes based on attached microbial growth |
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85 | (1) |
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4.11 Organic matter oxidation in the aeration tank |
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85 | (1) |
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86 | (1) |
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87 | (1) |
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87 | (6) |
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5 Environmental Contaminants: Treatment, Threats, Toxicity, and Tools for Sustainability |
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93 | (10) |
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5.1 Environmental contaminants |
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93 | (2) |
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95 | (1) |
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5.3 Membrane water treatment |
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95 | (1) |
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96 | (1) |
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5.5 Electrodialysis membrane treatment |
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96 | (1) |
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5.6 Catalytic processes: hydrogenation of nitrate and photocatalytic method |
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96 | (1) |
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5.7 Electrocatalytic oxidation |
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96 | (1) |
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5.8 Bioremediation and phytoremediation |
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97 | (1) |
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5.9 Biologically active carbon filtration |
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97 | (1) |
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97 | (1) |
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97 | (1) |
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5.12 Futuristic technologies for water treatment |
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98 | (1) |
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5.13 Treatment methods and salient models |
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98 | (1) |
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98 | (1) |
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5.15 Threats from heavy metals and other xenobiotics |
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99 | (1) |
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5.16 Toxicological implications and strategies for sustainability |
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100 | (1) |
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101 | (1) |
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101 | (2) |
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6 Improvement of Biodegradability Index of Industrial Wastewater Using Different Pretreatment Techniques |
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103 | (34) |
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103 | (1) |
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6.2 Characteristics of wastewater |
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104 | (3) |
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6.3 Overview of wastewater treatment process |
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107 | (2) |
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6.4 Biodegradation and its role in wastewater treatment |
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109 | (1) |
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6.5 Various pretreatment techniques for improvement of biodegradability index |
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110 | (21) |
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6.6 Summary and conclusion |
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131 | (2) |
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133 | (4) |
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7 Biota Debromination in Aqueous Media |
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137 | (50) |
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137 | (6) |
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7.2 Hexabromocyclododecane |
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143 | (12) |
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7.3 Tetrabromobisphenol A |
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155 | (10) |
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165 | (1) |
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166 | (21) |
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8 Application of Metatranscriptomics in Wastewater Treatment Processes |
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187 | (18) |
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Mutshiene Deogratias Ekwanzala |
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187 | (1) |
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8.2 Literature search of relevant studies |
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188 | (2) |
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190 | (8) |
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8.4 Challenges and future applications |
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198 | (3) |
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201 | (1) |
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202 | (3) |
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9 Role of Fungal Species in the Bioremediation of Metals |
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205 | (12) |
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Gladstone Christopher Jayakumar |
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205 | (4) |
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209 | (2) |
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9.3 Proteomic and genomic techniques for fungal bioremedial |
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211 | (1) |
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9.4 Life cycle assessment of the bioremedial process |
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212 | (1) |
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9.5 Prospects for fungal bioremediation |
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213 | (1) |
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214 | (3) |
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10 Molecular Biology Techniques for the Detection of Contaminants in Wastewater |
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217 | (20) |
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217 | (1) |
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10.2 Infectious contaminants of wastewater |
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218 | (3) |
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10.3 Noninfectious contaminants in wastewater |
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221 | (2) |
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10.4 Molecular detection methods |
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223 | (6) |
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229 | (1) |
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229 | (1) |
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229 | (8) |
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11 Current Treatment Technologies for Removal of Microplastic and Microfiber Pollutants From Wastewater |
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237 | (16) |
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237 | (2) |
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11.2 Sources and routes of microfiber particles liberation |
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239 | (1) |
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11.3 Contamination and toxicity |
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240 | (2) |
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11.4 Current and advanced treatment techniques |
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242 | (2) |
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11.5 Physical degradation of microplastics |
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244 | (1) |
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11.6 Chemical degradation of microplastics |
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245 | (1) |
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11.7 Biological degradation of microplastics |
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246 | (1) |
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247 | (1) |
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248 | (5) |
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12 Wastewater Treatment for Bioenergy Purposes Using a Metaproteomic Approach |
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253 | (26) |
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Rafael Dorighello Dadamuro |
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Tatiany Aparecida Teixeira Soratto |
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253 | (1) |
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12.2 Anaerobic digestion process |
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254 | (3) |
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12.3 Biohydrogen production by dark fermentation processes |
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257 | (1) |
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258 | (2) |
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12.5 Inhibition or improvement of biogas, hydrogen, and bioethanol production |
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260 | (1) |
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12.6 Promising enzymes in bioenergy production |
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261 | (4) |
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12.7 Metaproteomic data analysis |
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265 | (6) |
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271 | (1) |
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271 | (8) |
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13 Peracetic Acid in the Reuse of Treated Wastewaters |
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279 | (16) |
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279 | (1) |
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13.2 Water quality requirements for reuse |
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279 | (3) |
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13.3 Wastewater treatment options for reuse |
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282 | (1) |
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13.4 Peracetic acid in wastewater reuse |
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283 | (7) |
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290 | (1) |
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290 | (1) |
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290 | (5) |
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14 Bioelectrochemical Methods for the Recovery of Products From Wastewater |
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295 | (16) |
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295 | (1) |
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14.2 Bioelectrochemical systems |
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296 | (4) |
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14.3 Omics sciences in bioelectrochemical systems |
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300 | (4) |
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304 | (3) |
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307 | (1) |
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307 | (1) |
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307 | (4) |
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15 Microbes-Based Nanomaterials for the Wastewater Treatment and Decontamination of Water |
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311 | (16) |
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311 | (2) |
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15.2 Conventional methods for wastewater treatment |
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313 | (2) |
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15.3 Advanced techniques for wastewater treatment |
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315 | (1) |
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15.4 Various microbes-based nanomaterials in wastewater treatment |
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316 | (4) |
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320 | (1) |
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321 | (6) |
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16 Biological Wastewater Treatment Technology: Microalgae |
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327 | (16) |
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Richard Andi Solorzano Acosta |
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Celia Bertha Vargas-De-La-Cruz |
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327 | (1) |
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328 | (1) |
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16.3 Types of biological wastewater treatment technology |
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329 | (4) |
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16.4 Use of microalgae for effluent treatment |
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333 | (4) |
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337 | (1) |
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16.6 Conclusion and future challenges |
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337 | (1) |
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338 | (5) |
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17 Prokaryotic and Eukaryotic Diversity in Wastewater Treatment: Phenotypic Characterization, Molecular Techniques, and Bioprospecting |
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343 | (24) |
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Maria Gabriela Latorre Rapela |
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343 | (1) |
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17.2 Microbial metabolism roles in wastewater treatment |
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344 | (5) |
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17.3 Methods to study microbial composition and dynamics |
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349 | (9) |
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358 | (1) |
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359 | (1) |
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359 | (8) |
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18 Immobilized Microalgae for Removing Industrial Pollutants: A Greener Technique |
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367 | (18) |
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367 | (3) |
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370 | (3) |
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18.3 The concept of immobilization |
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373 | (3) |
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18.4 Use of immobilized microalgae in removing industrial pollutants |
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376 | (5) |
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381 | (1) |
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381 | (4) |
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19 Advances in Biotechnological Tools for Bioremediation of Wastewater Using Bacterial-Algal Symbiotic System |
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385 | (28) |
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385 | (3) |
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19.2 Bacterial---algal consortium |
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388 | (7) |
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19.3 Cultivation systems for wastewater treatment |
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395 | (3) |
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19.4 Modern biotechnological tools for improvement of bacterial---algal consortium |
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398 | (3) |
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19.5 Current challenges and research frontiers for the generation of value-added products from wastewater |
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401 | (1) |
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19.6 Industrial wastewater treatment---Indian---world scenario |
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402 | (1) |
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402 | (1) |
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403 | (10) |
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20 Algal-Based Wastewater Treatment and Biorefinery |
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413 | (20) |
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413 | (3) |
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416 | (3) |
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20.3 Application of wastewater in algal cultivation for biofuels and biochemical production |
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419 | (6) |
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20.4 Advancements in wastewater-based algal biomass production and biorefinery |
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425 | (2) |
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427 | (1) |
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427 | (6) |
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21 Application of Omics Tools for Microbial Community Structure and Function Analysis |
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433 | (24) |
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21.1 Introduction to microbial community |
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433 | (3) |
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21.2 Significance of microbial community |
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436 | (1) |
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21.3 Approaches to comprehend microbial communities |
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437 | (2) |
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21.4 Microbial community: structural and functional aspect |
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439 | (1) |
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21.5 Omics tool as an emerging approach |
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440 | (1) |
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21.6 Necessity of omics tool in modern research |
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441 | (3) |
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21.7 Prefacing metagenomic approaches |
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444 | (1) |
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445 | (1) |
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445 | (1) |
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446 | (1) |
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21.11 Bioinformatics in metaanalysis |
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447 | (4) |
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21.12 Conclusion and future prospectives |
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451 | (1) |
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451 | (5) |
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456 | (1) |
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22 Meta-Omics Studies of Microbial Communities in Hollow Fiber Membrane Biofilm Reactors Treating Contaminants in Water Resources: Recent Advances |
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457 | (14) |
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457 | (1) |
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22.2 Biofilm technologies in water treatment process |
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458 | (1) |
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22.3 Membrane biofilm reactor |
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459 | (1) |
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22.4 Types of membrane biofilm reactor |
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459 | (3) |
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22.5 Use of membrane biofilm reactor in different water treatment processes |
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462 | (1) |
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22.6 Meta-omics studies of biofilm communities |
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463 | (1) |
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22.7 Microbial communities developed in membrane biofilm reactors during treatment process |
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464 | (3) |
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467 | (4) |
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23 "Omics"---A Step Toward Understanding of Complex Diversity of the Microbial Community |
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471 | (18) |
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471 | (1) |
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23.2 Growing from biology: the early years |
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472 | (1) |
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23.3 The unculturable microorganism |
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473 | (1) |
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23.4 Creating the building blocks: the molecular era |
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473 | (1) |
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23.5 Molecular tools enabling an insight into the unknown |
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474 | (1) |
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23.6 Metagenomics and metatranscriptomics |
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474 | (2) |
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476 | (4) |
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23.8 Next-generation sequencing |
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480 | (1) |
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23.9 Advancement in omics era |
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481 | (1) |
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23.10 Limitations and future prospect |
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482 | (1) |
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482 | (1) |
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483 | (1) |
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483 | (6) |
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24 Advanced Omics Technologies: Relevant to Environment and Microbial Community |
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489 | (18) |
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489 | (1) |
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24.2 Omics tools in present scenario |
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490 | (4) |
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24.3 Dataset analyzing through MG-RAST |
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494 | (8) |
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502 | (3) |
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505 | (2) |
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25 Molecular Tools: Advance Approaches to Analyze Diversity of Microbial Community |
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507 | (14) |
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507 | (1) |
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25.2 Molecular approaches for analyzing microbial diversity |
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508 | (6) |
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25.3 Next-generation sequencing technologies in microbial ecology |
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514 | (1) |
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25.4 Metagenomic analysis of microbial communities |
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515 | (1) |
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516 | (1) |
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516 | (5) |
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26 Microbial Electrochemical Heavy Metal Removal: Fundamental to the Recent Development |
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521 | (22) |
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Abhilasha Singh Mathuriya |
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521 | (1) |
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26.2 Microbes involved in biodegradation at anode |
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522 | (1) |
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26.3 Materials used for construction |
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523 | (3) |
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26.4 The mechanism for removal of heavy metals |
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526 | (2) |
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26.5 Removal of heavy metals in microbial fuel cells |
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528 | (5) |
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26.6 Microbial fuel cell for treatment of heavy metals from groundwater |
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533 | (3) |
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26.7 Challenges in removal and recovery of heavy metals in microbial fuel cell |
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536 | (2) |
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538 | (1) |
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538 | (5) |
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27 Role of Modern Innovative Techniques for Assessing and Monitoring
Chapter Heavy Metal and Pesticide Pollution in Different Environs |
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543 | (10) |
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543 | (1) |
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27.2 Effects of heavy metals and pesticides as pollutants and their life cycle |
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544 | (2) |
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27.3 Modern innovative techniques for assessment and monitoring of heavy metal
Chapter and pesticide pollution |
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546 | (4) |
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550 | (3) |
| Index |
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553 | |
