Sustainability of Natural Resources: Planning, Development, and Management
Sustainability of Natural Resources: Planning, Development, and Management addresses water resources exploration, planning, recent geographic information system-based studies, and groundwater modeling and applications. It highlights the optimal strategies for sustainable water resources management a...
Gespeichert in:
| 1. Verfasser: | |
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| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Milton
Taylor & Francis Group
2024
|
| Ausgabe: | 1st ed |
| Online-Zugang: | DE-2070s |
| Zusammenfassung: | Sustainability of Natural Resources: Planning, Development, and Management addresses water resources exploration, planning, recent geographic information system-based studies, and groundwater modeling and applications. It highlights the optimal strategies for sustainable water resources management and development |
| Beschreibung: | Description based on publisher supplied metadata and other sources |
| Beschreibung: | 1 Online-Ressource (405 Seiten) |
| ISBN: | 9781040005408 |
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| 245 | 1 | 0 | |a Sustainability of Natural Resources |b Planning, Development, and Management |
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| 505 | 8 | |a Cover -- Half Title -- Title Page -- Copyright Page -- Dedication -- Table of Contents -- Preface -- Acknowledgements -- Editors' Biography -- List of Contributors -- Chapter 1 Characterization and Mapping of Soils for Sustainable Management Using Geospatial Techniques -- 1.1 Introduction -- 1.2 Materials and Methods -- 1.2.1 Study Area -- 1.2.2 Geology -- 1.2.3 Preparation of Base Maps -- 1.2.4 Ground-Truth Verification -- 1.2.5 Soil Sampling and Analysis -- 1.2.6 Soil Classification -- 1.2.7 Development of Soil Mapping Legend -- 1.2.8 Land Evaluation -- 1.3 Results and Discussion -- 1.3.1 Landform Delineation -- 1.3.2 Land-Use/Land Cover -- 1.3.3 Landform and Landscape Ecological Units (LEUs) -- 1.3.4 Soil-Landform Relationship -- 1.3.5 Soil Mapping -- 1.3.6 Soil Survey Interpretation -- 1.3.7 Surface Texture -- 1.3.8 Drainage -- 1.3.9 Soil Reaction (pH) -- 1.3.10 Organic Carbon -- 1.3.11 Available Nitrogen -- 1.3.12 Available Phosphorous -- 1.4 Available Potassium -- 1.5 Land Capability Classification -- 1.6 Soil Suitability for Crops -- 1.7 Recommendation -- 1.8 Conclusion -- Acknowledgments -- References -- Chapter 2 Sustainable Biodiversity Conservation in Tribal Area -- 2.1 Introduction -- 2.2 Tribes Role in Indigenous Botanical Knowledge (IBK) -- 2.3 Tribes Ethno Botany and Traditional Practices -- 2.4 Tribes Relationship with Flora Protection -- 2.5 Ethnic and Aboriginal Peoples' Role in Conservation -- 2.6 Tribal Relationship with Fauna -- 2.7 Tribes Role in Conservation of Insects -- 2.8 Tribes of Southern Indian -- 2.9 North Eastern Tribes -- 2.10 Tribes Association in Protecting Nature -- 2.11 Conclusion -- References -- Chapter 3 Soil Bioengineering Practices for Sustainable Ecosystem Restoration in Landslide-Affected Areas -- 3.1 Introduction -- 3.2 Ecosystem Deterioration and Need to Replenish -- 3.2.1 Evaluating the Area | |
| 505 | 8 | |a 3.2.2 Identifying Project Goals -- 3.2.3 Identifying and Removing Sources of Disturbance -- 3.2.4 Restoring Technologies -- 3.2.5 Substrates Rehabilitation -- 3.2.6 Vegetation Restoration -- 3.2.7 Monitoring and Maintenance -- 3.3 Landslides and Ecology Deterioration -- 3.4 Landslide Restoration -- 3.5 Landslide Restoration: Losses Incurred Directly vs. Indirectly -- 3.6 Landslide-Associated Problems and Their Mitigation & -- Management Measures -- 3.7 Bioengineering Strategy in Landslide Risk Mitigation -- 3.8 Application -- 3.9 Participation of the Social Environment in the Application and Succession of Soil Bioengineering -- 3.9.1 Seedlings -- 3.9.2 Bare Root Planting -- 3.9.3 Live Stakes -- 3.9.4 Contour Wattling -- 3.9.5 Brush Layer -- 3.9.6 Trench Packing -- 3.9.7 Brush Matting -- 3.9.8 Live Cuttings -- 3.9.9 Coir Fascines -- 3.9.10 Pre-Vegetated Mats -- 3.10 Slope Stability and Ecosystem Restoration -- 3.11 Native Species in Ecosystem Regeneration -- 3.12 Barrier to Ecological Restoration of Landslides -- 3.13 Indigenous People and their Support -- 3.14 Indigenous Knowledge in Ecosystem Restoration -- 3.15 Selection of Potential Indigenous Plants Based on Their Soil Reinforcement and Anchoring Capabilities -- 3.16 Recommendations -- 3.17 Conclusion -- References -- Chapter 4 Sustainable Ecosystem Development and Landscaping for Urban and Peri-Urban Areas -- 4.1 Introduction -- 4.2 Landscapes -- 4.2.1 Urban Landscape -- 4.2.2 Peri-Urban Landscape -- 4.3 Challenges -- 4.3.1 Role of Horticulture -- 4.3.2 Impact of Urbanization on Plant Life in Riparian Areas -- 4.3.3 Issues in Urban Ecology -- 4.3.4 Urban Ecology from a Landscape Perspective -- 4.3.5 Parks and Public Green Space -- 4.3.6 Multiple Benefits of Vegetated Land Cover to Health and Well-being -- 4.3.7 Plant Resources for Building the Urban Environments | |
| 505 | 8 | |a 4.3.8 Some of the Main Problems Confronting Urban Plants Include -- 4.3.9 Exotic Species in Urban/Peri-Urban Lanscaping -- 4.3.10 Role of Evergreen Plant in Urban/Peri-urban Landscaping -- 4.4 Conclusion -- References -- Chapter 5 Climate Change Impact of Fluoride Contamination on Human Health in Dry Zone of Sri Lanka -- 5.1 Introduction -- 5.2 Study Area -- 5.3 Climate Change and Fluoride Contamination in Groundwater -- 5.4 Groundwater Resources and Climate Change in Sri Lanka -- 5.5 Fluoride Contamination & -- Health Issues in Dry Zone Sri Lanka -- 5.6 Conclusion -- References -- Chapter 6 Application of Geospatial Technology in Catchment Modeling Using SCS-CN Method for Estimating the Direct Runoff on Barakar River Basin, Jharkhand -- 6.1 Introduction -- 6.2 Study Area -- 6.3 Materials and Methods -- 6.3.1 Data Sources -- 6.4 SCS-CN Method -- 6.4.1 Estimation of S -- 6.4.2 Determination of CN -- 6.4.3 Selection of CN -- 6.5 Methodology -- 6.6 Results and Discussion -- 6.6.1 Watershed Delineation -- 6.6.2 Landuse-Landcover Map -- 6.6.3 Soil Map -- 6.6.4 Soil Landuse Vegetation Complex (SLV) Map -- 6.6.5 Curve Number (CN) and Weighted Curve Number (WCN) Values -- 6.7 Antecedent Moisture Conditions, CN I and CN III Values -- 6.8 Potential Maximum Retention (S) and Runoff Depth (Q) -- 6.9 Conclusion -- References -- Chapter 7 Hydro-Geospatial Investigation to Propose Water Conservation Sites for Water Management in Limestone Terrain -- 7.1 Introduction -- 7.2 Study Area -- 7.2.1 Location -- 7.2.2 Climate -- 7.2.3 Geology -- 7.2.4 Lineament -- 7.2.5 Geomorphology -- 7.2.6 Drainage -- 7.2.7 Land use/Land Cover -- 7.2.8 Soils -- 7.2.9 Slope -- 7.3 Materials and Methods -- 7.4 Results and Discussion -- 7.5 Lithology -- 7.6 Lineament Density -- 7.7 Geomorphology -- 7.8 Drainage Density -- 7.9 Rainfall -- 7.10 Land Use/Land Cover (LULC) -- 7.11 Slope | |
| 505 | 8 | |a 7.12 Soil -- 7.13 Terrain Wetness Index (TWI) -- 7.14 Validation -- 7.15 Conclusion -- 7.15.1 Proposed Artificial Recharge Structure -- Acknowledgements -- References -- Chapter 8 Rainfall Spatiotemporal Variability and Trends in the Semi-Arid Ecological Zone of Nigeria -- 8.1 Introduction -- 8.2 Study Area -- 8.3 Materials and Methods -- 8.3.1 Data Sources -- 8.3.2 Trend and Variability Detection -- 8.3.3 Spatial Interpolation -- 8.4 Results and Discussion -- 8.5 Rainfall Characteristics -- 8.5.1 Statistical Overview of Rainfall Climatology -- 8.5.2 Rainfall Variability and Anomaly Patterns -- 8.6 Annual, Interannual, and Monthly Trends -- 8.7 Trends Detection Based on the WMO Standardized Period -- 8.8 Implications for Agriculture and Water Ecosystem Services -- 8.9 Conclusion -- Acknowledgments -- References -- Chapter 9 Climate Change Awareness, Perception, and Adaptation Strategies for Small and Marginal Farmers in Yobe State, Nigeria -- 9.1 Introduction -- 9.2 Materials and Methods -- 9.3 Study Area -- 9.4 Data Compilation Techniques -- 9.5 Sampling Procedures -- 9.6 Analysis of Data -- 9.7 Results and Discussion -- 9.7.1 The Socio-economic and Institutional Characteristics of Respondents -- 9.7.2 Farmers' Awareness of Changes in Climate Parameters -- 9.7.3 Climate Change Information for Farmers -- 9.8 Climate Change and Farmers' Perceptions -- 9.9 Factors that Influence Farmers' Perceptions of Climate Change -- 9.10 Farmers' Climate Change Adaptation -- 9.11 Constraints Facing Farmers as a Result of Climate Change -- 9.12 Conclusion and Recommendation -- Acknowledgment -- References -- Chapter 10 Delineation of Groundwater Prospect Zones based on Earth Observation Data and AHP Modeling - A Study from Basaltic Rock Formation -- 10.1 Introduction -- 10.2 Study Area Description -- 10.3 Materials and Methods -- 10.3.1 Used Datasets | |
| 505 | 8 | |a 10.3.2 Methodology -- 10.3.3 AHP Method and Weight Normalization -- 10.3.4 Weighted Overlay Analysis (WOA) -- 10.3.5 Groundwater Fluctuation -- 10.3.6 Accuracy Assessment -- 10.4 Results and Discussion -- 10.4.1 LULC -- 10.4.2 Landforms and Geomorphological Features -- 10.4.3 Lineament Density -- 10.4.4 Drainage Map -- 10.4.5 Groundwater Fluctuation -- 10.4.6 Geology -- 10.4.7 Slope -- 10.4.8 Soil -- 10.4.9 Rainfall -- 10.5 Groundwater Prospective Zone Mapping -- 10.6 Validation -- 10.7 Conclusion -- Conflict of Interest -- References -- Chapter 11 Hydro-geochemical Evaluation of Phreatic Groundwater for Assessing Drinking and Irrigation Appropriateness - A Case Study of Chandrapur Watershed -- 11.1 Introduction -- 11.2 Fluorite (CaF2 ) Mineralization in Geological Environment -- 11.2.1 Physical Characteristics of Fluorite (CAF2 ) -- 11.2.2 High Concentration of F in Groundwater -- 11.2.3 Genesis of Fluorite (CaF2 ) Mineralization in Study Area -- 11.3 Study Area Details -- 11.4 Materials and Methods -- 11.5 Physicochemical Characteristics of Groundwater -- 11.5.1 Physical Parameters -- 11.5.2 Cation-Anion Chemistry -- 11.5.3 Rock-Water Interaction -- 11.6 Discussion on Groundwater Appropriateness -- 11.6.1 Drinking and General Domestic Use -- 11.6.2 Irrigation Use -- 11.7 F-Contents from Study Area -- 11.8 Conclusions -- References -- Chapter 12 Variability of Ground Water Quality in Quaternary Aquifers of the Cauvery and Vennar Sub-basins within the Cauvery Delta, Southern India -- 12.1 Introduction -- 12.2 Materials and Methods -- 12.2.1 Study Area -- 12.2.2 Geology and Hydrogeology -- 12.2.3 Groundwater Sampling and Laboratory Analysis -- 12.2.4 Drinking Water Quality -- 12.3 Results and Discussion -- 12.4 Drinking Water Quality -- 12.4.1 pH -- 12.4.2 Electrical Conductivity -- 12.4.3 Total Dissolved Solids -- 12.4.4 Total Hardness | |
| 505 | 8 | |a 12.4.5 Calcium | |
| 520 | |a Sustainability of Natural Resources: Planning, Development, and Management addresses water resources exploration, planning, recent geographic information system-based studies, and groundwater modeling and applications. It highlights the optimal strategies for sustainable water resources management and development | ||
| 700 | 1 | |a Moharir, Kanak N. |e Sonstige |4 oth | |
| 700 | 1 | |a Singh, Vijay P. |e Sonstige |4 oth | |
| 700 | 1 | |a Pande, Chaitanya B. |e Sonstige |4 oth | |
| 700 | 1 | |a Varade, Abhay M. |e Sonstige |4 oth | |
| 776 | 0 | 8 | |i Erscheint auch als |n Druck-Ausgabe |a Kumar, Rohitashw |t Sustainability of Natural Resources |d Milton : Taylor & Francis Group,c2024 |z 9781032295312 |
| 912 | |a ZDB-30-PQE | ||
| 943 | 1 | |a oai:aleph.bib-bvb.de:BVB01-035215183 | |
| 966 | e | |u https://ebookcentral.proquest.com/lib/hwr/detail.action?docID=31354689 |l DE-2070s |p ZDB-30-PQE |q HWR_PDA_PQE |x Aggregator |3 Volltext | |
Datensatz im Suchindex
| _version_ | 1810600654168653824 |
|---|---|
| adam_text | |
| any_adam_object | |
| author | Kumar, Rohitashw |
| author_facet | Kumar, Rohitashw |
| author_role | aut |
| author_sort | Kumar, Rohitashw |
| author_variant | r k rk |
| building | Verbundindex |
| bvnumber | BV049875725 |
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| contents | Cover -- Half Title -- Title Page -- Copyright Page -- Dedication -- Table of Contents -- Preface -- Acknowledgements -- Editors' Biography -- List of Contributors -- Chapter 1 Characterization and Mapping of Soils for Sustainable Management Using Geospatial Techniques -- 1.1 Introduction -- 1.2 Materials and Methods -- 1.2.1 Study Area -- 1.2.2 Geology -- 1.2.3 Preparation of Base Maps -- 1.2.4 Ground-Truth Verification -- 1.2.5 Soil Sampling and Analysis -- 1.2.6 Soil Classification -- 1.2.7 Development of Soil Mapping Legend -- 1.2.8 Land Evaluation -- 1.3 Results and Discussion -- 1.3.1 Landform Delineation -- 1.3.2 Land-Use/Land Cover -- 1.3.3 Landform and Landscape Ecological Units (LEUs) -- 1.3.4 Soil-Landform Relationship -- 1.3.5 Soil Mapping -- 1.3.6 Soil Survey Interpretation -- 1.3.7 Surface Texture -- 1.3.8 Drainage -- 1.3.9 Soil Reaction (pH) -- 1.3.10 Organic Carbon -- 1.3.11 Available Nitrogen -- 1.3.12 Available Phosphorous -- 1.4 Available Potassium -- 1.5 Land Capability Classification -- 1.6 Soil Suitability for Crops -- 1.7 Recommendation -- 1.8 Conclusion -- Acknowledgments -- References -- Chapter 2 Sustainable Biodiversity Conservation in Tribal Area -- 2.1 Introduction -- 2.2 Tribes Role in Indigenous Botanical Knowledge (IBK) -- 2.3 Tribes Ethno Botany and Traditional Practices -- 2.4 Tribes Relationship with Flora Protection -- 2.5 Ethnic and Aboriginal Peoples' Role in Conservation -- 2.6 Tribal Relationship with Fauna -- 2.7 Tribes Role in Conservation of Insects -- 2.8 Tribes of Southern Indian -- 2.9 North Eastern Tribes -- 2.10 Tribes Association in Protecting Nature -- 2.11 Conclusion -- References -- Chapter 3 Soil Bioengineering Practices for Sustainable Ecosystem Restoration in Landslide-Affected Areas -- 3.1 Introduction -- 3.2 Ecosystem Deterioration and Need to Replenish -- 3.2.1 Evaluating the Area 3.2.2 Identifying Project Goals -- 3.2.3 Identifying and Removing Sources of Disturbance -- 3.2.4 Restoring Technologies -- 3.2.5 Substrates Rehabilitation -- 3.2.6 Vegetation Restoration -- 3.2.7 Monitoring and Maintenance -- 3.3 Landslides and Ecology Deterioration -- 3.4 Landslide Restoration -- 3.5 Landslide Restoration: Losses Incurred Directly vs. Indirectly -- 3.6 Landslide-Associated Problems and Their Mitigation & -- Management Measures -- 3.7 Bioengineering Strategy in Landslide Risk Mitigation -- 3.8 Application -- 3.9 Participation of the Social Environment in the Application and Succession of Soil Bioengineering -- 3.9.1 Seedlings -- 3.9.2 Bare Root Planting -- 3.9.3 Live Stakes -- 3.9.4 Contour Wattling -- 3.9.5 Brush Layer -- 3.9.6 Trench Packing -- 3.9.7 Brush Matting -- 3.9.8 Live Cuttings -- 3.9.9 Coir Fascines -- 3.9.10 Pre-Vegetated Mats -- 3.10 Slope Stability and Ecosystem Restoration -- 3.11 Native Species in Ecosystem Regeneration -- 3.12 Barrier to Ecological Restoration of Landslides -- 3.13 Indigenous People and their Support -- 3.14 Indigenous Knowledge in Ecosystem Restoration -- 3.15 Selection of Potential Indigenous Plants Based on Their Soil Reinforcement and Anchoring Capabilities -- 3.16 Recommendations -- 3.17 Conclusion -- References -- Chapter 4 Sustainable Ecosystem Development and Landscaping for Urban and Peri-Urban Areas -- 4.1 Introduction -- 4.2 Landscapes -- 4.2.1 Urban Landscape -- 4.2.2 Peri-Urban Landscape -- 4.3 Challenges -- 4.3.1 Role of Horticulture -- 4.3.2 Impact of Urbanization on Plant Life in Riparian Areas -- 4.3.3 Issues in Urban Ecology -- 4.3.4 Urban Ecology from a Landscape Perspective -- 4.3.5 Parks and Public Green Space -- 4.3.6 Multiple Benefits of Vegetated Land Cover to Health and Well-being -- 4.3.7 Plant Resources for Building the Urban Environments 4.3.8 Some of the Main Problems Confronting Urban Plants Include -- 4.3.9 Exotic Species in Urban/Peri-Urban Lanscaping -- 4.3.10 Role of Evergreen Plant in Urban/Peri-urban Landscaping -- 4.4 Conclusion -- References -- Chapter 5 Climate Change Impact of Fluoride Contamination on Human Health in Dry Zone of Sri Lanka -- 5.1 Introduction -- 5.2 Study Area -- 5.3 Climate Change and Fluoride Contamination in Groundwater -- 5.4 Groundwater Resources and Climate Change in Sri Lanka -- 5.5 Fluoride Contamination & -- Health Issues in Dry Zone Sri Lanka -- 5.6 Conclusion -- References -- Chapter 6 Application of Geospatial Technology in Catchment Modeling Using SCS-CN Method for Estimating the Direct Runoff on Barakar River Basin, Jharkhand -- 6.1 Introduction -- 6.2 Study Area -- 6.3 Materials and Methods -- 6.3.1 Data Sources -- 6.4 SCS-CN Method -- 6.4.1 Estimation of S -- 6.4.2 Determination of CN -- 6.4.3 Selection of CN -- 6.5 Methodology -- 6.6 Results and Discussion -- 6.6.1 Watershed Delineation -- 6.6.2 Landuse-Landcover Map -- 6.6.3 Soil Map -- 6.6.4 Soil Landuse Vegetation Complex (SLV) Map -- 6.6.5 Curve Number (CN) and Weighted Curve Number (WCN) Values -- 6.7 Antecedent Moisture Conditions, CN I and CN III Values -- 6.8 Potential Maximum Retention (S) and Runoff Depth (Q) -- 6.9 Conclusion -- References -- Chapter 7 Hydro-Geospatial Investigation to Propose Water Conservation Sites for Water Management in Limestone Terrain -- 7.1 Introduction -- 7.2 Study Area -- 7.2.1 Location -- 7.2.2 Climate -- 7.2.3 Geology -- 7.2.4 Lineament -- 7.2.5 Geomorphology -- 7.2.6 Drainage -- 7.2.7 Land use/Land Cover -- 7.2.8 Soils -- 7.2.9 Slope -- 7.3 Materials and Methods -- 7.4 Results and Discussion -- 7.5 Lithology -- 7.6 Lineament Density -- 7.7 Geomorphology -- 7.8 Drainage Density -- 7.9 Rainfall -- 7.10 Land Use/Land Cover (LULC) -- 7.11 Slope 7.12 Soil -- 7.13 Terrain Wetness Index (TWI) -- 7.14 Validation -- 7.15 Conclusion -- 7.15.1 Proposed Artificial Recharge Structure -- Acknowledgements -- References -- Chapter 8 Rainfall Spatiotemporal Variability and Trends in the Semi-Arid Ecological Zone of Nigeria -- 8.1 Introduction -- 8.2 Study Area -- 8.3 Materials and Methods -- 8.3.1 Data Sources -- 8.3.2 Trend and Variability Detection -- 8.3.3 Spatial Interpolation -- 8.4 Results and Discussion -- 8.5 Rainfall Characteristics -- 8.5.1 Statistical Overview of Rainfall Climatology -- 8.5.2 Rainfall Variability and Anomaly Patterns -- 8.6 Annual, Interannual, and Monthly Trends -- 8.7 Trends Detection Based on the WMO Standardized Period -- 8.8 Implications for Agriculture and Water Ecosystem Services -- 8.9 Conclusion -- Acknowledgments -- References -- Chapter 9 Climate Change Awareness, Perception, and Adaptation Strategies for Small and Marginal Farmers in Yobe State, Nigeria -- 9.1 Introduction -- 9.2 Materials and Methods -- 9.3 Study Area -- 9.4 Data Compilation Techniques -- 9.5 Sampling Procedures -- 9.6 Analysis of Data -- 9.7 Results and Discussion -- 9.7.1 The Socio-economic and Institutional Characteristics of Respondents -- 9.7.2 Farmers' Awareness of Changes in Climate Parameters -- 9.7.3 Climate Change Information for Farmers -- 9.8 Climate Change and Farmers' Perceptions -- 9.9 Factors that Influence Farmers' Perceptions of Climate Change -- 9.10 Farmers' Climate Change Adaptation -- 9.11 Constraints Facing Farmers as a Result of Climate Change -- 9.12 Conclusion and Recommendation -- Acknowledgment -- References -- Chapter 10 Delineation of Groundwater Prospect Zones based on Earth Observation Data and AHP Modeling - A Study from Basaltic Rock Formation -- 10.1 Introduction -- 10.2 Study Area Description -- 10.3 Materials and Methods -- 10.3.1 Used Datasets 10.3.2 Methodology -- 10.3.3 AHP Method and Weight Normalization -- 10.3.4 Weighted Overlay Analysis (WOA) -- 10.3.5 Groundwater Fluctuation -- 10.3.6 Accuracy Assessment -- 10.4 Results and Discussion -- 10.4.1 LULC -- 10.4.2 Landforms and Geomorphological Features -- 10.4.3 Lineament Density -- 10.4.4 Drainage Map -- 10.4.5 Groundwater Fluctuation -- 10.4.6 Geology -- 10.4.7 Slope -- 10.4.8 Soil -- 10.4.9 Rainfall -- 10.5 Groundwater Prospective Zone Mapping -- 10.6 Validation -- 10.7 Conclusion -- Conflict of Interest -- References -- Chapter 11 Hydro-geochemical Evaluation of Phreatic Groundwater for Assessing Drinking and Irrigation Appropriateness - A Case Study of Chandrapur Watershed -- 11.1 Introduction -- 11.2 Fluorite (CaF2 ) Mineralization in Geological Environment -- 11.2.1 Physical Characteristics of Fluorite (CAF2 ) -- 11.2.2 High Concentration of F in Groundwater -- 11.2.3 Genesis of Fluorite (CaF2 ) Mineralization in Study Area -- 11.3 Study Area Details -- 11.4 Materials and Methods -- 11.5 Physicochemical Characteristics of Groundwater -- 11.5.1 Physical Parameters -- 11.5.2 Cation-Anion Chemistry -- 11.5.3 Rock-Water Interaction -- 11.6 Discussion on Groundwater Appropriateness -- 11.6.1 Drinking and General Domestic Use -- 11.6.2 Irrigation Use -- 11.7 F-Contents from Study Area -- 11.8 Conclusions -- References -- Chapter 12 Variability of Ground Water Quality in Quaternary Aquifers of the Cauvery and Vennar Sub-basins within the Cauvery Delta, Southern India -- 12.1 Introduction -- 12.2 Materials and Methods -- 12.2.1 Study Area -- 12.2.2 Geology and Hydrogeology -- 12.2.3 Groundwater Sampling and Laboratory Analysis -- 12.2.4 Drinking Water Quality -- 12.3 Results and Discussion -- 12.4 Drinking Water Quality -- 12.4.1 pH -- 12.4.2 Electrical Conductivity -- 12.4.3 Total Dissolved Solids -- 12.4.4 Total Hardness 12.4.5 Calcium |
| ctrlnum | (ZDB-30-PQE)EBC31354689 (ZDB-30-PAD)EBC31354689 (ZDB-89-EBL)EBL31354689 (OCoLC)1436830690 (DE-599)BVBBV049875725 |
| dewey-full | 333.91/04 |
| dewey-hundreds | 300 - Social sciences |
| dewey-ones | 333 - Economics of land and energy |
| dewey-raw | 333.91/04 |
| dewey-search | 333.91/04 |
| dewey-sort | 3333.91 14 |
| dewey-tens | 330 - Economics |
| discipline | Wirtschaftswissenschaften |
| edition | 1st ed |
| format | Electronic eBook |
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List of Contributors -- Chapter 1 Characterization and Mapping of Soils for Sustainable Management Using Geospatial Techniques -- 1.1 Introduction -- 1.2 Materials and Methods -- 1.2.1 Study Area -- 1.2.2 Geology -- 1.2.3 Preparation of Base Maps -- 1.2.4 Ground-Truth Verification -- 1.2.5 Soil Sampling and Analysis -- 1.2.6 Soil Classification -- 1.2.7 Development of Soil Mapping Legend -- 1.2.8 Land Evaluation -- 1.3 Results and Discussion -- 1.3.1 Landform Delineation -- 1.3.2 Land-Use/Land Cover -- 1.3.3 Landform and Landscape Ecological Units (LEUs) -- 1.3.4 Soil-Landform Relationship -- 1.3.5 Soil Mapping -- 1.3.6 Soil Survey Interpretation -- 1.3.7 Surface Texture -- 1.3.8 Drainage -- 1.3.9 Soil Reaction (pH) -- 1.3.10 Organic Carbon -- 1.3.11 Available Nitrogen -- 1.3.12 Available Phosphorous -- 1.4 Available Potassium -- 1.5 Land Capability Classification -- 1.6 Soil Suitability for Crops -- 1.7 Recommendation -- 1.8 Conclusion -- Acknowledgments -- References -- Chapter 2 Sustainable Biodiversity Conservation in Tribal Area -- 2.1 Introduction -- 2.2 Tribes Role in Indigenous Botanical Knowledge (IBK) -- 2.3 Tribes Ethno Botany and Traditional Practices -- 2.4 Tribes Relationship with Flora Protection -- 2.5 Ethnic and Aboriginal Peoples' Role in Conservation -- 2.6 Tribal Relationship with Fauna -- 2.7 Tribes Role in Conservation of Insects -- 2.8 Tribes of Southern Indian -- 2.9 North Eastern Tribes -- 2.10 Tribes Association in Protecting Nature -- 2.11 Conclusion -- References -- Chapter 3 Soil Bioengineering Practices for Sustainable Ecosystem Restoration in Landslide-Affected Areas -- 3.1 Introduction -- 3.2 Ecosystem Deterioration and Need to Replenish -- 3.2.1 Evaluating the Area</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">3.2.2 Identifying Project Goals -- 3.2.3 Identifying and Removing Sources of Disturbance -- 3.2.4 Restoring Technologies -- 3.2.5 Substrates Rehabilitation -- 3.2.6 Vegetation Restoration -- 3.2.7 Monitoring and Maintenance -- 3.3 Landslides and Ecology Deterioration -- 3.4 Landslide Restoration -- 3.5 Landslide Restoration: Losses Incurred Directly vs. Indirectly -- 3.6 Landslide-Associated Problems and Their Mitigation &amp -- Management Measures -- 3.7 Bioengineering Strategy in Landslide Risk Mitigation -- 3.8 Application -- 3.9 Participation of the Social Environment in the Application and Succession of Soil Bioengineering -- 3.9.1 Seedlings -- 3.9.2 Bare Root Planting -- 3.9.3 Live Stakes -- 3.9.4 Contour Wattling -- 3.9.5 Brush Layer -- 3.9.6 Trench Packing -- 3.9.7 Brush Matting -- 3.9.8 Live Cuttings -- 3.9.9 Coir Fascines -- 3.9.10 Pre-Vegetated Mats -- 3.10 Slope Stability and Ecosystem Restoration -- 3.11 Native Species in Ecosystem Regeneration -- 3.12 Barrier to Ecological Restoration of Landslides -- 3.13 Indigenous People and their Support -- 3.14 Indigenous Knowledge in Ecosystem Restoration -- 3.15 Selection of Potential Indigenous Plants Based on Their Soil Reinforcement and Anchoring Capabilities -- 3.16 Recommendations -- 3.17 Conclusion -- References -- Chapter 4 Sustainable Ecosystem Development and Landscaping for Urban and Peri-Urban Areas -- 4.1 Introduction -- 4.2 Landscapes -- 4.2.1 Urban Landscape -- 4.2.2 Peri-Urban Landscape -- 4.3 Challenges -- 4.3.1 Role of Horticulture -- 4.3.2 Impact of Urbanization on Plant Life in Riparian Areas -- 4.3.3 Issues in Urban Ecology -- 4.3.4 Urban Ecology from a Landscape Perspective -- 4.3.5 Parks and Public Green Space -- 4.3.6 Multiple Benefits of Vegetated Land Cover to Health and Well-being -- 4.3.7 Plant Resources for Building the Urban Environments</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">4.3.8 Some of the Main Problems Confronting Urban Plants Include -- 4.3.9 Exotic Species in Urban/Peri-Urban Lanscaping -- 4.3.10 Role of Evergreen Plant in Urban/Peri-urban Landscaping -- 4.4 Conclusion -- References -- Chapter 5 Climate Change Impact of Fluoride Contamination on Human Health in Dry Zone of Sri Lanka -- 5.1 Introduction -- 5.2 Study Area -- 5.3 Climate Change and Fluoride Contamination in Groundwater -- 5.4 Groundwater Resources and Climate Change in Sri Lanka -- 5.5 Fluoride Contamination &amp -- Health Issues in Dry Zone Sri Lanka -- 5.6 Conclusion -- References -- Chapter 6 Application of Geospatial Technology in Catchment Modeling Using SCS-CN Method for Estimating the Direct Runoff on Barakar River Basin, Jharkhand -- 6.1 Introduction -- 6.2 Study Area -- 6.3 Materials and Methods -- 6.3.1 Data Sources -- 6.4 SCS-CN Method -- 6.4.1 Estimation of S -- 6.4.2 Determination of CN -- 6.4.3 Selection of CN -- 6.5 Methodology -- 6.6 Results and Discussion -- 6.6.1 Watershed Delineation -- 6.6.2 Landuse-Landcover Map -- 6.6.3 Soil Map -- 6.6.4 Soil Landuse Vegetation Complex (SLV) Map -- 6.6.5 Curve Number (CN) and Weighted Curve Number (WCN) Values -- 6.7 Antecedent Moisture Conditions, CN I and CN III Values -- 6.8 Potential Maximum Retention (S) and Runoff Depth (Q) -- 6.9 Conclusion -- References -- Chapter 7 Hydro-Geospatial Investigation to Propose Water Conservation Sites for Water Management in Limestone Terrain -- 7.1 Introduction -- 7.2 Study Area -- 7.2.1 Location -- 7.2.2 Climate -- 7.2.3 Geology -- 7.2.4 Lineament -- 7.2.5 Geomorphology -- 7.2.6 Drainage -- 7.2.7 Land use/Land Cover -- 7.2.8 Soils -- 7.2.9 Slope -- 7.3 Materials and Methods -- 7.4 Results and Discussion -- 7.5 Lithology -- 7.6 Lineament Density -- 7.7 Geomorphology -- 7.8 Drainage Density -- 7.9 Rainfall -- 7.10 Land Use/Land Cover (LULC) -- 7.11 Slope</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">7.12 Soil -- 7.13 Terrain Wetness Index (TWI) -- 7.14 Validation -- 7.15 Conclusion -- 7.15.1 Proposed Artificial Recharge Structure -- Acknowledgements -- References -- Chapter 8 Rainfall Spatiotemporal Variability and Trends in the Semi-Arid Ecological Zone of Nigeria -- 8.1 Introduction -- 8.2 Study Area -- 8.3 Materials and Methods -- 8.3.1 Data Sources -- 8.3.2 Trend and Variability Detection -- 8.3.3 Spatial Interpolation -- 8.4 Results and Discussion -- 8.5 Rainfall Characteristics -- 8.5.1 Statistical Overview of Rainfall Climatology -- 8.5.2 Rainfall Variability and Anomaly Patterns -- 8.6 Annual, Interannual, and Monthly Trends -- 8.7 Trends Detection Based on the WMO Standardized Period -- 8.8 Implications for Agriculture and Water Ecosystem Services -- 8.9 Conclusion -- Acknowledgments -- References -- Chapter 9 Climate Change Awareness, Perception, and Adaptation Strategies for Small and Marginal Farmers in Yobe State, Nigeria -- 9.1 Introduction -- 9.2 Materials and Methods -- 9.3 Study Area -- 9.4 Data Compilation Techniques -- 9.5 Sampling Procedures -- 9.6 Analysis of Data -- 9.7 Results and Discussion -- 9.7.1 The Socio-economic and Institutional Characteristics of Respondents -- 9.7.2 Farmers' Awareness of Changes in Climate Parameters -- 9.7.3 Climate Change Information for Farmers -- 9.8 Climate Change and Farmers' Perceptions -- 9.9 Factors that Influence Farmers' Perceptions of Climate Change -- 9.10 Farmers' Climate Change Adaptation -- 9.11 Constraints Facing Farmers as a Result of Climate Change -- 9.12 Conclusion and Recommendation -- Acknowledgment -- References -- Chapter 10 Delineation of Groundwater Prospect Zones based on Earth Observation Data and AHP Modeling - A Study from Basaltic Rock Formation -- 10.1 Introduction -- 10.2 Study Area Description -- 10.3 Materials and Methods -- 10.3.1 Used Datasets</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">10.3.2 Methodology -- 10.3.3 AHP Method and Weight Normalization -- 10.3.4 Weighted Overlay Analysis (WOA) -- 10.3.5 Groundwater Fluctuation -- 10.3.6 Accuracy Assessment -- 10.4 Results and Discussion -- 10.4.1 LULC -- 10.4.2 Landforms and Geomorphological Features -- 10.4.3 Lineament Density -- 10.4.4 Drainage Map -- 10.4.5 Groundwater Fluctuation -- 10.4.6 Geology -- 10.4.7 Slope -- 10.4.8 Soil -- 10.4.9 Rainfall -- 10.5 Groundwater Prospective Zone Mapping -- 10.6 Validation -- 10.7 Conclusion -- Conflict of Interest -- References -- Chapter 11 Hydro-geochemical Evaluation of Phreatic Groundwater for Assessing Drinking and Irrigation Appropriateness - A Case Study of Chandrapur Watershed -- 11.1 Introduction -- 11.2 Fluorite (CaF2 ) Mineralization in Geological Environment -- 11.2.1 Physical Characteristics of Fluorite (CAF2 ) -- 11.2.2 High Concentration of F in Groundwater -- 11.2.3 Genesis of Fluorite (CaF2 ) Mineralization in Study Area -- 11.3 Study Area Details -- 11.4 Materials and Methods -- 11.5 Physicochemical Characteristics of Groundwater -- 11.5.1 Physical Parameters -- 11.5.2 Cation-Anion Chemistry -- 11.5.3 Rock-Water Interaction -- 11.6 Discussion on Groundwater Appropriateness -- 11.6.1 Drinking and General Domestic Use -- 11.6.2 Irrigation Use -- 11.7 F-Contents from Study Area -- 11.8 Conclusions -- References -- Chapter 12 Variability of Ground Water Quality in Quaternary Aquifers of the Cauvery and Vennar Sub-basins within the Cauvery Delta, Southern India -- 12.1 Introduction -- 12.2 Materials and Methods -- 12.2.1 Study Area -- 12.2.2 Geology and Hydrogeology -- 12.2.3 Groundwater Sampling and Laboratory Analysis -- 12.2.4 Drinking Water Quality -- 12.3 Results and Discussion -- 12.4 Drinking Water Quality -- 12.4.1 pH -- 12.4.2 Electrical Conductivity -- 12.4.3 Total Dissolved Solids -- 12.4.4 Total Hardness</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">12.4.5 Calcium</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">Sustainability of Natural Resources: Planning, Development, and Management addresses water resources exploration, planning, recent geographic information system-based studies, and groundwater modeling and applications. 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| id | DE-604.BV049875725 |
| illustrated | Not Illustrated |
| indexdate | 2024-09-19T05:22:20Z |
| institution | BVB |
| isbn | 9781040005408 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-035215183 |
| oclc_num | 1436830690 |
| open_access_boolean | |
| owner | DE-2070s |
| owner_facet | DE-2070s |
| physical | 1 Online-Ressource (405 Seiten) |
| psigel | ZDB-30-PQE ZDB-30-PQE HWR_PDA_PQE |
| publishDate | 2024 |
| publishDateSearch | 2024 |
| publishDateSort | 2024 |
| publisher | Taylor & Francis Group |
| record_format | marc |
| spelling | Kumar, Rohitashw Verfasser aut Sustainability of Natural Resources Planning, Development, and Management 1st ed Milton Taylor & Francis Group 2024 ©2024 1 Online-Ressource (405 Seiten) txt rdacontent c rdamedia cr rdacarrier Description based on publisher supplied metadata and other sources Cover -- Half Title -- Title Page -- Copyright Page -- Dedication -- Table of Contents -- Preface -- Acknowledgements -- Editors' Biography -- List of Contributors -- Chapter 1 Characterization and Mapping of Soils for Sustainable Management Using Geospatial Techniques -- 1.1 Introduction -- 1.2 Materials and Methods -- 1.2.1 Study Area -- 1.2.2 Geology -- 1.2.3 Preparation of Base Maps -- 1.2.4 Ground-Truth Verification -- 1.2.5 Soil Sampling and Analysis -- 1.2.6 Soil Classification -- 1.2.7 Development of Soil Mapping Legend -- 1.2.8 Land Evaluation -- 1.3 Results and Discussion -- 1.3.1 Landform Delineation -- 1.3.2 Land-Use/Land Cover -- 1.3.3 Landform and Landscape Ecological Units (LEUs) -- 1.3.4 Soil-Landform Relationship -- 1.3.5 Soil Mapping -- 1.3.6 Soil Survey Interpretation -- 1.3.7 Surface Texture -- 1.3.8 Drainage -- 1.3.9 Soil Reaction (pH) -- 1.3.10 Organic Carbon -- 1.3.11 Available Nitrogen -- 1.3.12 Available Phosphorous -- 1.4 Available Potassium -- 1.5 Land Capability Classification -- 1.6 Soil Suitability for Crops -- 1.7 Recommendation -- 1.8 Conclusion -- Acknowledgments -- References -- Chapter 2 Sustainable Biodiversity Conservation in Tribal Area -- 2.1 Introduction -- 2.2 Tribes Role in Indigenous Botanical Knowledge (IBK) -- 2.3 Tribes Ethno Botany and Traditional Practices -- 2.4 Tribes Relationship with Flora Protection -- 2.5 Ethnic and Aboriginal Peoples' Role in Conservation -- 2.6 Tribal Relationship with Fauna -- 2.7 Tribes Role in Conservation of Insects -- 2.8 Tribes of Southern Indian -- 2.9 North Eastern Tribes -- 2.10 Tribes Association in Protecting Nature -- 2.11 Conclusion -- References -- Chapter 3 Soil Bioengineering Practices for Sustainable Ecosystem Restoration in Landslide-Affected Areas -- 3.1 Introduction -- 3.2 Ecosystem Deterioration and Need to Replenish -- 3.2.1 Evaluating the Area 3.2.2 Identifying Project Goals -- 3.2.3 Identifying and Removing Sources of Disturbance -- 3.2.4 Restoring Technologies -- 3.2.5 Substrates Rehabilitation -- 3.2.6 Vegetation Restoration -- 3.2.7 Monitoring and Maintenance -- 3.3 Landslides and Ecology Deterioration -- 3.4 Landslide Restoration -- 3.5 Landslide Restoration: Losses Incurred Directly vs. Indirectly -- 3.6 Landslide-Associated Problems and Their Mitigation & -- Management Measures -- 3.7 Bioengineering Strategy in Landslide Risk Mitigation -- 3.8 Application -- 3.9 Participation of the Social Environment in the Application and Succession of Soil Bioengineering -- 3.9.1 Seedlings -- 3.9.2 Bare Root Planting -- 3.9.3 Live Stakes -- 3.9.4 Contour Wattling -- 3.9.5 Brush Layer -- 3.9.6 Trench Packing -- 3.9.7 Brush Matting -- 3.9.8 Live Cuttings -- 3.9.9 Coir Fascines -- 3.9.10 Pre-Vegetated Mats -- 3.10 Slope Stability and Ecosystem Restoration -- 3.11 Native Species in Ecosystem Regeneration -- 3.12 Barrier to Ecological Restoration of Landslides -- 3.13 Indigenous People and their Support -- 3.14 Indigenous Knowledge in Ecosystem Restoration -- 3.15 Selection of Potential Indigenous Plants Based on Their Soil Reinforcement and Anchoring Capabilities -- 3.16 Recommendations -- 3.17 Conclusion -- References -- Chapter 4 Sustainable Ecosystem Development and Landscaping for Urban and Peri-Urban Areas -- 4.1 Introduction -- 4.2 Landscapes -- 4.2.1 Urban Landscape -- 4.2.2 Peri-Urban Landscape -- 4.3 Challenges -- 4.3.1 Role of Horticulture -- 4.3.2 Impact of Urbanization on Plant Life in Riparian Areas -- 4.3.3 Issues in Urban Ecology -- 4.3.4 Urban Ecology from a Landscape Perspective -- 4.3.5 Parks and Public Green Space -- 4.3.6 Multiple Benefits of Vegetated Land Cover to Health and Well-being -- 4.3.7 Plant Resources for Building the Urban Environments 4.3.8 Some of the Main Problems Confronting Urban Plants Include -- 4.3.9 Exotic Species in Urban/Peri-Urban Lanscaping -- 4.3.10 Role of Evergreen Plant in Urban/Peri-urban Landscaping -- 4.4 Conclusion -- References -- Chapter 5 Climate Change Impact of Fluoride Contamination on Human Health in Dry Zone of Sri Lanka -- 5.1 Introduction -- 5.2 Study Area -- 5.3 Climate Change and Fluoride Contamination in Groundwater -- 5.4 Groundwater Resources and Climate Change in Sri Lanka -- 5.5 Fluoride Contamination & -- Health Issues in Dry Zone Sri Lanka -- 5.6 Conclusion -- References -- Chapter 6 Application of Geospatial Technology in Catchment Modeling Using SCS-CN Method for Estimating the Direct Runoff on Barakar River Basin, Jharkhand -- 6.1 Introduction -- 6.2 Study Area -- 6.3 Materials and Methods -- 6.3.1 Data Sources -- 6.4 SCS-CN Method -- 6.4.1 Estimation of S -- 6.4.2 Determination of CN -- 6.4.3 Selection of CN -- 6.5 Methodology -- 6.6 Results and Discussion -- 6.6.1 Watershed Delineation -- 6.6.2 Landuse-Landcover Map -- 6.6.3 Soil Map -- 6.6.4 Soil Landuse Vegetation Complex (SLV) Map -- 6.6.5 Curve Number (CN) and Weighted Curve Number (WCN) Values -- 6.7 Antecedent Moisture Conditions, CN I and CN III Values -- 6.8 Potential Maximum Retention (S) and Runoff Depth (Q) -- 6.9 Conclusion -- References -- Chapter 7 Hydro-Geospatial Investigation to Propose Water Conservation Sites for Water Management in Limestone Terrain -- 7.1 Introduction -- 7.2 Study Area -- 7.2.1 Location -- 7.2.2 Climate -- 7.2.3 Geology -- 7.2.4 Lineament -- 7.2.5 Geomorphology -- 7.2.6 Drainage -- 7.2.7 Land use/Land Cover -- 7.2.8 Soils -- 7.2.9 Slope -- 7.3 Materials and Methods -- 7.4 Results and Discussion -- 7.5 Lithology -- 7.6 Lineament Density -- 7.7 Geomorphology -- 7.8 Drainage Density -- 7.9 Rainfall -- 7.10 Land Use/Land Cover (LULC) -- 7.11 Slope 7.12 Soil -- 7.13 Terrain Wetness Index (TWI) -- 7.14 Validation -- 7.15 Conclusion -- 7.15.1 Proposed Artificial Recharge Structure -- Acknowledgements -- References -- Chapter 8 Rainfall Spatiotemporal Variability and Trends in the Semi-Arid Ecological Zone of Nigeria -- 8.1 Introduction -- 8.2 Study Area -- 8.3 Materials and Methods -- 8.3.1 Data Sources -- 8.3.2 Trend and Variability Detection -- 8.3.3 Spatial Interpolation -- 8.4 Results and Discussion -- 8.5 Rainfall Characteristics -- 8.5.1 Statistical Overview of Rainfall Climatology -- 8.5.2 Rainfall Variability and Anomaly Patterns -- 8.6 Annual, Interannual, and Monthly Trends -- 8.7 Trends Detection Based on the WMO Standardized Period -- 8.8 Implications for Agriculture and Water Ecosystem Services -- 8.9 Conclusion -- Acknowledgments -- References -- Chapter 9 Climate Change Awareness, Perception, and Adaptation Strategies for Small and Marginal Farmers in Yobe State, Nigeria -- 9.1 Introduction -- 9.2 Materials and Methods -- 9.3 Study Area -- 9.4 Data Compilation Techniques -- 9.5 Sampling Procedures -- 9.6 Analysis of Data -- 9.7 Results and Discussion -- 9.7.1 The Socio-economic and Institutional Characteristics of Respondents -- 9.7.2 Farmers' Awareness of Changes in Climate Parameters -- 9.7.3 Climate Change Information for Farmers -- 9.8 Climate Change and Farmers' Perceptions -- 9.9 Factors that Influence Farmers' Perceptions of Climate Change -- 9.10 Farmers' Climate Change Adaptation -- 9.11 Constraints Facing Farmers as a Result of Climate Change -- 9.12 Conclusion and Recommendation -- Acknowledgment -- References -- Chapter 10 Delineation of Groundwater Prospect Zones based on Earth Observation Data and AHP Modeling - A Study from Basaltic Rock Formation -- 10.1 Introduction -- 10.2 Study Area Description -- 10.3 Materials and Methods -- 10.3.1 Used Datasets 10.3.2 Methodology -- 10.3.3 AHP Method and Weight Normalization -- 10.3.4 Weighted Overlay Analysis (WOA) -- 10.3.5 Groundwater Fluctuation -- 10.3.6 Accuracy Assessment -- 10.4 Results and Discussion -- 10.4.1 LULC -- 10.4.2 Landforms and Geomorphological Features -- 10.4.3 Lineament Density -- 10.4.4 Drainage Map -- 10.4.5 Groundwater Fluctuation -- 10.4.6 Geology -- 10.4.7 Slope -- 10.4.8 Soil -- 10.4.9 Rainfall -- 10.5 Groundwater Prospective Zone Mapping -- 10.6 Validation -- 10.7 Conclusion -- Conflict of Interest -- References -- Chapter 11 Hydro-geochemical Evaluation of Phreatic Groundwater for Assessing Drinking and Irrigation Appropriateness - A Case Study of Chandrapur Watershed -- 11.1 Introduction -- 11.2 Fluorite (CaF2 ) Mineralization in Geological Environment -- 11.2.1 Physical Characteristics of Fluorite (CAF2 ) -- 11.2.2 High Concentration of F in Groundwater -- 11.2.3 Genesis of Fluorite (CaF2 ) Mineralization in Study Area -- 11.3 Study Area Details -- 11.4 Materials and Methods -- 11.5 Physicochemical Characteristics of Groundwater -- 11.5.1 Physical Parameters -- 11.5.2 Cation-Anion Chemistry -- 11.5.3 Rock-Water Interaction -- 11.6 Discussion on Groundwater Appropriateness -- 11.6.1 Drinking and General Domestic Use -- 11.6.2 Irrigation Use -- 11.7 F-Contents from Study Area -- 11.8 Conclusions -- References -- Chapter 12 Variability of Ground Water Quality in Quaternary Aquifers of the Cauvery and Vennar Sub-basins within the Cauvery Delta, Southern India -- 12.1 Introduction -- 12.2 Materials and Methods -- 12.2.1 Study Area -- 12.2.2 Geology and Hydrogeology -- 12.2.3 Groundwater Sampling and Laboratory Analysis -- 12.2.4 Drinking Water Quality -- 12.3 Results and Discussion -- 12.4 Drinking Water Quality -- 12.4.1 pH -- 12.4.2 Electrical Conductivity -- 12.4.3 Total Dissolved Solids -- 12.4.4 Total Hardness 12.4.5 Calcium Sustainability of Natural Resources: Planning, Development, and Management addresses water resources exploration, planning, recent geographic information system-based studies, and groundwater modeling and applications. It highlights the optimal strategies for sustainable water resources management and development Moharir, Kanak N. Sonstige oth Singh, Vijay P. Sonstige oth Pande, Chaitanya B. Sonstige oth Varade, Abhay M. Sonstige oth Erscheint auch als Druck-Ausgabe Kumar, Rohitashw Sustainability of Natural Resources Milton : Taylor & Francis Group,c2024 9781032295312 |
| spellingShingle | Kumar, Rohitashw Sustainability of Natural Resources Planning, Development, and Management Cover -- Half Title -- Title Page -- Copyright Page -- Dedication -- Table of Contents -- Preface -- Acknowledgements -- Editors' Biography -- List of Contributors -- Chapter 1 Characterization and Mapping of Soils for Sustainable Management Using Geospatial Techniques -- 1.1 Introduction -- 1.2 Materials and Methods -- 1.2.1 Study Area -- 1.2.2 Geology -- 1.2.3 Preparation of Base Maps -- 1.2.4 Ground-Truth Verification -- 1.2.5 Soil Sampling and Analysis -- 1.2.6 Soil Classification -- 1.2.7 Development of Soil Mapping Legend -- 1.2.8 Land Evaluation -- 1.3 Results and Discussion -- 1.3.1 Landform Delineation -- 1.3.2 Land-Use/Land Cover -- 1.3.3 Landform and Landscape Ecological Units (LEUs) -- 1.3.4 Soil-Landform Relationship -- 1.3.5 Soil Mapping -- 1.3.6 Soil Survey Interpretation -- 1.3.7 Surface Texture -- 1.3.8 Drainage -- 1.3.9 Soil Reaction (pH) -- 1.3.10 Organic Carbon -- 1.3.11 Available Nitrogen -- 1.3.12 Available Phosphorous -- 1.4 Available Potassium -- 1.5 Land Capability Classification -- 1.6 Soil Suitability for Crops -- 1.7 Recommendation -- 1.8 Conclusion -- Acknowledgments -- References -- Chapter 2 Sustainable Biodiversity Conservation in Tribal Area -- 2.1 Introduction -- 2.2 Tribes Role in Indigenous Botanical Knowledge (IBK) -- 2.3 Tribes Ethno Botany and Traditional Practices -- 2.4 Tribes Relationship with Flora Protection -- 2.5 Ethnic and Aboriginal Peoples' Role in Conservation -- 2.6 Tribal Relationship with Fauna -- 2.7 Tribes Role in Conservation of Insects -- 2.8 Tribes of Southern Indian -- 2.9 North Eastern Tribes -- 2.10 Tribes Association in Protecting Nature -- 2.11 Conclusion -- References -- Chapter 3 Soil Bioengineering Practices for Sustainable Ecosystem Restoration in Landslide-Affected Areas -- 3.1 Introduction -- 3.2 Ecosystem Deterioration and Need to Replenish -- 3.2.1 Evaluating the Area 3.2.2 Identifying Project Goals -- 3.2.3 Identifying and Removing Sources of Disturbance -- 3.2.4 Restoring Technologies -- 3.2.5 Substrates Rehabilitation -- 3.2.6 Vegetation Restoration -- 3.2.7 Monitoring and Maintenance -- 3.3 Landslides and Ecology Deterioration -- 3.4 Landslide Restoration -- 3.5 Landslide Restoration: Losses Incurred Directly vs. Indirectly -- 3.6 Landslide-Associated Problems and Their Mitigation & -- Management Measures -- 3.7 Bioengineering Strategy in Landslide Risk Mitigation -- 3.8 Application -- 3.9 Participation of the Social Environment in the Application and Succession of Soil Bioengineering -- 3.9.1 Seedlings -- 3.9.2 Bare Root Planting -- 3.9.3 Live Stakes -- 3.9.4 Contour Wattling -- 3.9.5 Brush Layer -- 3.9.6 Trench Packing -- 3.9.7 Brush Matting -- 3.9.8 Live Cuttings -- 3.9.9 Coir Fascines -- 3.9.10 Pre-Vegetated Mats -- 3.10 Slope Stability and Ecosystem Restoration -- 3.11 Native Species in Ecosystem Regeneration -- 3.12 Barrier to Ecological Restoration of Landslides -- 3.13 Indigenous People and their Support -- 3.14 Indigenous Knowledge in Ecosystem Restoration -- 3.15 Selection of Potential Indigenous Plants Based on Their Soil Reinforcement and Anchoring Capabilities -- 3.16 Recommendations -- 3.17 Conclusion -- References -- Chapter 4 Sustainable Ecosystem Development and Landscaping for Urban and Peri-Urban Areas -- 4.1 Introduction -- 4.2 Landscapes -- 4.2.1 Urban Landscape -- 4.2.2 Peri-Urban Landscape -- 4.3 Challenges -- 4.3.1 Role of Horticulture -- 4.3.2 Impact of Urbanization on Plant Life in Riparian Areas -- 4.3.3 Issues in Urban Ecology -- 4.3.4 Urban Ecology from a Landscape Perspective -- 4.3.5 Parks and Public Green Space -- 4.3.6 Multiple Benefits of Vegetated Land Cover to Health and Well-being -- 4.3.7 Plant Resources for Building the Urban Environments 4.3.8 Some of the Main Problems Confronting Urban Plants Include -- 4.3.9 Exotic Species in Urban/Peri-Urban Lanscaping -- 4.3.10 Role of Evergreen Plant in Urban/Peri-urban Landscaping -- 4.4 Conclusion -- References -- Chapter 5 Climate Change Impact of Fluoride Contamination on Human Health in Dry Zone of Sri Lanka -- 5.1 Introduction -- 5.2 Study Area -- 5.3 Climate Change and Fluoride Contamination in Groundwater -- 5.4 Groundwater Resources and Climate Change in Sri Lanka -- 5.5 Fluoride Contamination & -- Health Issues in Dry Zone Sri Lanka -- 5.6 Conclusion -- References -- Chapter 6 Application of Geospatial Technology in Catchment Modeling Using SCS-CN Method for Estimating the Direct Runoff on Barakar River Basin, Jharkhand -- 6.1 Introduction -- 6.2 Study Area -- 6.3 Materials and Methods -- 6.3.1 Data Sources -- 6.4 SCS-CN Method -- 6.4.1 Estimation of S -- 6.4.2 Determination of CN -- 6.4.3 Selection of CN -- 6.5 Methodology -- 6.6 Results and Discussion -- 6.6.1 Watershed Delineation -- 6.6.2 Landuse-Landcover Map -- 6.6.3 Soil Map -- 6.6.4 Soil Landuse Vegetation Complex (SLV) Map -- 6.6.5 Curve Number (CN) and Weighted Curve Number (WCN) Values -- 6.7 Antecedent Moisture Conditions, CN I and CN III Values -- 6.8 Potential Maximum Retention (S) and Runoff Depth (Q) -- 6.9 Conclusion -- References -- Chapter 7 Hydro-Geospatial Investigation to Propose Water Conservation Sites for Water Management in Limestone Terrain -- 7.1 Introduction -- 7.2 Study Area -- 7.2.1 Location -- 7.2.2 Climate -- 7.2.3 Geology -- 7.2.4 Lineament -- 7.2.5 Geomorphology -- 7.2.6 Drainage -- 7.2.7 Land use/Land Cover -- 7.2.8 Soils -- 7.2.9 Slope -- 7.3 Materials and Methods -- 7.4 Results and Discussion -- 7.5 Lithology -- 7.6 Lineament Density -- 7.7 Geomorphology -- 7.8 Drainage Density -- 7.9 Rainfall -- 7.10 Land Use/Land Cover (LULC) -- 7.11 Slope 7.12 Soil -- 7.13 Terrain Wetness Index (TWI) -- 7.14 Validation -- 7.15 Conclusion -- 7.15.1 Proposed Artificial Recharge Structure -- Acknowledgements -- References -- Chapter 8 Rainfall Spatiotemporal Variability and Trends in the Semi-Arid Ecological Zone of Nigeria -- 8.1 Introduction -- 8.2 Study Area -- 8.3 Materials and Methods -- 8.3.1 Data Sources -- 8.3.2 Trend and Variability Detection -- 8.3.3 Spatial Interpolation -- 8.4 Results and Discussion -- 8.5 Rainfall Characteristics -- 8.5.1 Statistical Overview of Rainfall Climatology -- 8.5.2 Rainfall Variability and Anomaly Patterns -- 8.6 Annual, Interannual, and Monthly Trends -- 8.7 Trends Detection Based on the WMO Standardized Period -- 8.8 Implications for Agriculture and Water Ecosystem Services -- 8.9 Conclusion -- Acknowledgments -- References -- Chapter 9 Climate Change Awareness, Perception, and Adaptation Strategies for Small and Marginal Farmers in Yobe State, Nigeria -- 9.1 Introduction -- 9.2 Materials and Methods -- 9.3 Study Area -- 9.4 Data Compilation Techniques -- 9.5 Sampling Procedures -- 9.6 Analysis of Data -- 9.7 Results and Discussion -- 9.7.1 The Socio-economic and Institutional Characteristics of Respondents -- 9.7.2 Farmers' Awareness of Changes in Climate Parameters -- 9.7.3 Climate Change Information for Farmers -- 9.8 Climate Change and Farmers' Perceptions -- 9.9 Factors that Influence Farmers' Perceptions of Climate Change -- 9.10 Farmers' Climate Change Adaptation -- 9.11 Constraints Facing Farmers as a Result of Climate Change -- 9.12 Conclusion and Recommendation -- Acknowledgment -- References -- Chapter 10 Delineation of Groundwater Prospect Zones based on Earth Observation Data and AHP Modeling - A Study from Basaltic Rock Formation -- 10.1 Introduction -- 10.2 Study Area Description -- 10.3 Materials and Methods -- 10.3.1 Used Datasets 10.3.2 Methodology -- 10.3.3 AHP Method and Weight Normalization -- 10.3.4 Weighted Overlay Analysis (WOA) -- 10.3.5 Groundwater Fluctuation -- 10.3.6 Accuracy Assessment -- 10.4 Results and Discussion -- 10.4.1 LULC -- 10.4.2 Landforms and Geomorphological Features -- 10.4.3 Lineament Density -- 10.4.4 Drainage Map -- 10.4.5 Groundwater Fluctuation -- 10.4.6 Geology -- 10.4.7 Slope -- 10.4.8 Soil -- 10.4.9 Rainfall -- 10.5 Groundwater Prospective Zone Mapping -- 10.6 Validation -- 10.7 Conclusion -- Conflict of Interest -- References -- Chapter 11 Hydro-geochemical Evaluation of Phreatic Groundwater for Assessing Drinking and Irrigation Appropriateness - A Case Study of Chandrapur Watershed -- 11.1 Introduction -- 11.2 Fluorite (CaF2 ) Mineralization in Geological Environment -- 11.2.1 Physical Characteristics of Fluorite (CAF2 ) -- 11.2.2 High Concentration of F in Groundwater -- 11.2.3 Genesis of Fluorite (CaF2 ) Mineralization in Study Area -- 11.3 Study Area Details -- 11.4 Materials and Methods -- 11.5 Physicochemical Characteristics of Groundwater -- 11.5.1 Physical Parameters -- 11.5.2 Cation-Anion Chemistry -- 11.5.3 Rock-Water Interaction -- 11.6 Discussion on Groundwater Appropriateness -- 11.6.1 Drinking and General Domestic Use -- 11.6.2 Irrigation Use -- 11.7 F-Contents from Study Area -- 11.8 Conclusions -- References -- Chapter 12 Variability of Ground Water Quality in Quaternary Aquifers of the Cauvery and Vennar Sub-basins within the Cauvery Delta, Southern India -- 12.1 Introduction -- 12.2 Materials and Methods -- 12.2.1 Study Area -- 12.2.2 Geology and Hydrogeology -- 12.2.3 Groundwater Sampling and Laboratory Analysis -- 12.2.4 Drinking Water Quality -- 12.3 Results and Discussion -- 12.4 Drinking Water Quality -- 12.4.1 pH -- 12.4.2 Electrical Conductivity -- 12.4.3 Total Dissolved Solids -- 12.4.4 Total Hardness 12.4.5 Calcium |
| title | Sustainability of Natural Resources Planning, Development, and Management |
| title_auth | Sustainability of Natural Resources Planning, Development, and Management |
| title_exact_search | Sustainability of Natural Resources Planning, Development, and Management |
| title_full | Sustainability of Natural Resources Planning, Development, and Management |
| title_fullStr | Sustainability of Natural Resources Planning, Development, and Management |
| title_full_unstemmed | Sustainability of Natural Resources Planning, Development, and Management |
| title_short | Sustainability of Natural Resources |
| title_sort | sustainability of natural resources planning development and management |
| title_sub | Planning, Development, and Management |
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