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024 7 $a10.1007/978-3-032-08362-3
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035   $a(DE-He213)978-3-032-08362-3
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100   $a20260108d2026      u|         0
101 0 $aeng
135   $aur|||||||||||
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aNature-Based Solutions for Decentralised Liquid Waste Management /$fedited by Smita S. Kumar, Vivek Kumar
205   $a1st ed. 2026.
210  1$aCham :$cSpringer Nature Switzerland :$cImprint: Springer,$d2026.
215   $a1 online resource (525 pages)
225 1 $aEnvironmental Challenges and Solutions,$x2214-2835
311 08$a3-032-08361-3 
327   $aPart I. Introduction -- Chapter 1. Nature-Based Solutions for Decentralized Liquid Waste Management -- Part II. Decentralized Technologies for Wastewater Treatment -- Chapter 2. Constructed Wetland as a Sustainable Option to Decentralized System for Industrial Waste Water Treatment -- Chapter 3. Waste Stabilization Ponds for Decentralized Wastewater Treatment -- Chapter 4. Access to Clean Water: Sustainable Biochar-based Water Treatment -- Chapter 5. Recent Advances in Anaerobic Baffled Reactor Technology for Decentralized Wastewater Management -- Chapter 6. Prospects and Advances in Soil Biotechnology as a Sustainable Strategy for Decentralized Liquid Waste Management -- Chapter 7. Treatment of Emerging Contaminants Using Constructed Wetlands -- Chapter 8. Landfill Leachate Treatment Using Sustainable Technology: Current Practices and Perspectives -- Chapter 9. Microbial Technologies for Degradation of Microplastics in Wastewater -- Chapter 10. Innovative Nature-Based Solutions for Hazardous Effluent Treatment -- Chapter 11. Application of Constructed Wetlands for the Removal of Contaminants from Wastewater -- Chapter 12. Macrophytes as a Potential Sustainable Strategy for Decentralized Wastewater Treatment -- Chapter 13. Circularity and Nature Based Solutions: A New Paradigm for Sustainability -- Part III. Case Studies -- Chapter 14. A Low-Cost Appropriate Sanitation Technology for Rural India: A Case Study of Vadgaon Maval, India -- Chapter 15. Application of Phytoremediation Technology as a Cost-Effective Solution for Treatment of Municipal and Industrial Wastewater: A Few Case Studies -- Chapter 16. Environmentally Sound Wastewater Treatment Options in Hebbal-Nagavara Valley, Bengaluru -- Chapter 17. Performance Evaluation of Raw Rubber Treatment of Wastewater in Water Lettuce (Pistia stratiotes) Macrophyte Pond -- Chapter 18. Performance Assessment of a Field-Scale Constructed Wetland: A Case Study of Tepla Village, Ambala, Haryana.
330   $aWhen water is used once and is no longer fit for human consumption or any other use, it is considered liquid waste. Proper disposal, treatment and reuse of wastewater wherever possible will help in combating diseases as well as meeting water scarcity. The selection and adoption of appropriate technologies plays a very important role in this whole exercise and has far-reaching implications on the success in achieving a circular water economy. The selection of technologies is even more important. New concepts are continuously being added to achieve a sustainable society, focusing on the new tool of circular economy. Various reuse options of waste; either water or solids (e.g., agricultural irrigation, industrial process recycling, resource recovery, biogas production etc.) as part of a circular economy, are being identified and tested. This book caters to the role of nature-based solutions in a circular water economy and includes chapters on how to tackle wastewater treatment with the help of sustainable bio-based technologies. This may include Bio-based technologies for the treatment of domestic/municipal/industrial/agro-industrial wastewater/sludges including but not limited to: Leach pit, Soak pit, Magic Pits, Kitchen Garden, and Community Soak pits etc. Waste Stabilization Ponds Duck Weed Pond system Constructed Wetlands Soil Bio Technology DEWATS Reed bed System Anaerobic Baffled Reactor (ABR) Moving Bed Bio-Film Reactor (MBBR) Urine treatment technologies The book covers increased efficiency of treatment for example by using process modification, integration of technologies or selectively enriched biota. Investigation of pollutant removal processes/transformations, to better understand and optimize the design and improve the performance of these wastewater treatment systems are also included.
410  0$aEnvironmental Challenges and Solutions,$x2214-2835
606   $aBioremediation
606   $aPlant biotechnology
606   $aFreshwater ecology
606   $aMarine ecology
606   $aSoil science
606   $aWater
606   $aHydrology
606   $aEnvironmental protection
606   $aCivil engineering
606   $aEnvironmental Biotechnology
606   $aPlant Biotechnology
606   $aFreshwater and Marine Ecology
606   $aSoil Science
606   $aWater
606   $aSoil and Water Protection
615  0$aBioremediation.
615  0$aPlant biotechnology.
615  0$aFreshwater ecology.
615  0$aMarine ecology.
615  0$aSoil science.
615  0$aWater.
615  0$aHydrology.
615  0$aEnvironmental protection.
615  0$aCivil engineering.
615 14$aEnvironmental Biotechnology.
615 24$aPlant Biotechnology.
615 24$aFreshwater and Marine Ecology.
615 24$aSoil Science.
615 24$aWater.
615 24$aSoil and Water Protection.
676   $a628.5
676   $a660.6
700   $aKumar$b Smita S$01889464
701   $aKumar$b Uthaya$01888346
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9911054610103321
996   $aNature-Based Solutions for Decentralised Liquid Waste Management$94532974
997   $aUNINA