Verfügbarkeit: Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture

Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture:

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Bibliographische Detailangaben
Weitere Verfasser:	Bundschuh, Jochen 1960- (HerausgeberIn), Chen, Guangnan (HerausgeberIn), Chandrasekharam, Dornadula 1948- (HerausgeberIn), Piechocki, Janusz (HerausgeberIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	London CRC Press [2017]
Schriftenreihe:	Sustainable Energy Developments Volume 13
Schlagworte:	Aquakultur Landwirtschaft Windenergie Geothermik Aufsatzsammlung
Online-Zugang:	Inhaltsverzeichnis Klappentext
Beschreibung:	xliv, 359 Seiten Illustrationen, Diagramme, Karten
ISBN:	9781138029705

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Datensatz im Suchindex

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adam_text	Table of contents About the book series vii Editorial board ix List of contributors xxxiii Foreword by Alessandro Flammini xxxvii Editor’s preface xxxix About the editors xli 1. Solar, wind and geothermal energy applications in agriculture: back to the future? 1 Jochen Bundschuh, Guangnan Chen, Barbara Tomaszewska, Noreddine Ghaffour, Shahbaz Mushtaq, Ihsan Hamawand' Kathryn Reardon-Smith, Tek Maraseni, Thomas Banhazi, Hacene Mahmoudi, Mattheus Goosen Diogenes L. Antille 1.1 Introduction 1 1.2 Energy demands in agriculture 2 1.2.1 Energy use in agriculture 2 1.2.2 The energy management process 2 1.3 The water-energy-food-climate nexus 3 1.4 Greenhouse gas emissions and carbon footprint of agriculture 4 1.4.1 Sources of greenhouse gas emissions from agriculture 4 1.4.2 Overview of global agricultural emissions 4 1.4.3 Life cycle assessment (LCA) 5 1.4.4 Comparison of environmental impact of different foods 6 1.5 Merging renewables with agriculture: The sustainability approach 6 1.5.1 Solar photovoltaic energy applications 6 1.5.1.1 Water pumping 7 1.5.2 Solar and geothermal direct heat applications 8 1.5.2.1 Heating/cooling of spaces* buildings, soil and water 8 1.5.2.2 Drying of crops, fruits, grains and animal products 9 1.5.2.3 Heating of greenhouses 10 1.5.3 Wind power applications 10 1.5.4 Multi-use of agricultural land for food and electric power production 11 1.5.5 Agriculture within the cascade system of geothermal direct heat utilization 11 1.5.6 Renewables for water desalination and food security: decoupling freshwater production from fossil fuel supply 12 1.5.7 Geothermal and solar greenhouse heating/cooling, ventilation, humidification, desalination 19 1.5.7.1 Solar and geothermal based greenhouse development 19 1.5.7.2 Closed seawater greenhouses for meeting water, energy and food security 24 1.5.8 The present market of renewable energy technologies 24 1.6 Conclusions 25 2. Agriculture sector modernization and renewable energy development: perspectives from developing countries 33 Robert K. Dixon Ming Yang 2.1 Introduction 33 2.1.1 Challenges to renewable energy development 33 2.1.2 Opportunities for renewable energy in developing countries and countries with economies in transition 34 2.2 The role of the Global Environment Facility 35 2.2.1 The GEF’s renewable energy and energy-efficiency strategies 36 2.2.2 The GEF’s renewable energy portfolio 37 2.2.3 The GEF’s renewable energy portfolio and the modernization of agriculture 40 2.3 Biomass energy 41 2.3.1 Case study: Thailand - biomass co-generation 41 2.3.2 Case study: India - biomass gasification 41 2.3.3 Case study: Latvia ֊ biomass combustion 42 2.4 Combined renewable energy technologies 42 2.4.1 Case study: India ֊ combined renewable energy technologies 42 2.5 Geothermal energy 43 2.5.1 Case study: The Philippines ֊ geothermal power 43 2.6 Small hydropower 44 2.6.1 Case study: Indonesia - small hydropower 44 2.7 Off-grid solar photovoltaic 44 2.7.1 Case study: India - off-grid photovoltaic 45 2.8 On-grid solar photovoltaic 45 2.8.1 Case study: Philippines ֊ on-grid photovoltaic 45 2.9 Solar thermal heating 46 2.9.1 Case study: Tunisia - solar water heating 46 2.10 Solar thermal power 46 2.10.1 Case study: Egypt - solar thermal power 47 2.10.2 Case study Morocco - concentrating solar power 47 2.11 Wind power 47 2.11.1 Case study: China - wind power 48 2.11.2 Case study: Mexico - wind power 48 2.12 Summary and conclusions 49 3. Linking food and nutrition security, urban and peri-urban agriculture, and sustainable energy use: experiences from South America 51 Deborah Hines £ Sarah Balistreri 3.1 Introduction 51 3.1.1 The global food and nutrition security context 51 3.2 Multiple benefits from urban and peri-urban agriculture actions 52 3.2.1 UPA and food and nutrition benefits 53 3.2.2 UPA and women’s empowerment 53 3.2.3 UPA and environmental benefits 54 3.2.3.1 UPA and carbon footprint mitigation 54 3.2.3.2 UPA and sustainable water systems 55 3.3 Urban agriculture: examples from South America 56 3.3.1 UPA in Ecuador 56 3.3.1.1 Participative urban agriculture in Quito, Ecuador 57 3.3.1.2 WFP urban agriculture initiatives in Ecuador 60 3.3,2 Innovative UPA practices in Colombia 63 3.3.2.1 UPA powered by renewable energy in La Guajira, Colombia 65 3.4 Shaping the food and nutrition security agenda 68 4. Renewable energy use for aquaponics development on a global scale towards sustainable food production 73 Ragnheidur Thorarinsdottir, Daniel Coaten, Edoardo Pantanella, Charlie Shultz, Henk Stander Kristin Vala Ragnarsdottir 4.1 Introduction 73 4.2 Aquaponics technology 82 4.2.1 Simple recirculating units 82 4.2.2 Modern RAS and hydroponics 83 4.2.3 Resource intensity 84 4.2.4 Integrated multi-trophic approach 85 4.3 Aquaponics as a sustainable food production method 85 4.3.1 Types of products 85 4.3.1.1 Fish 85 4.3.1.2 Terrestrial plants 85 4.3.1.3 Other species 85 4.3.2 Control and safety 86 4.3.3 Efficient use of resources 87 4.3.3.1 Renewable energy sources 87 4.3.3.2 Energy efficiency and waste streams 89 4.3.3.3 Savings through well-designed integration 89 4.4 Connection to UN Sustainable Development Goals 2015-2030 90 4.4.1 UN Sustainable Development Goals 90 4.4.1.1 Goal 2 End hunger, achieve food security and improved nutrition and promote sustainable agriculture 90 4.4.1.2 Goal 3 Ensure healthy lives and promote well-being for all at all ages 90 4.4.1.3 Goal 6 Ensure access to water and sanitation for all 90 4.4.1.4 Goal 7 Ensure access to affordable, reliable, sustainable and modem energy for all 91 4.4.1.5 Goal 8 Promote inclusive and sustainable economic growth, employment and decent work for all 91 4.4.1.6 Goal 9 Build resilient infrastructure, promote sustainable industrialization and foster innovation 91 4.4.1.7 Goal 11 Make cities inclusive, safe, resilient and sustainable 91 4.4.1.8 Goal 12 Ensure sustainable consumption and production patterns 91 4.4.1.9 Goal 13 Take urgent action to combat climate change and its impacts 91 4.4.1.10 Goal 14 Conserve and sustainably use the oceans, seas and marine resources 91 4.4.1.11 Goal 15 Sustainably manage forests, combat desertification, halt and reverse land degradation, halt biodiversity loss 91 4.5 Conclusions and future work 91 4.5.1 Conclusions 91 4.5.2 Future work 92 5. Renewable energy use and potential in remote central Australia 97 Yiheyis Maru, Supriya Mathew, Digby Race Bruno Spandonide 5.1 Introduction 97 5.2 Renewable energy supply: state and trends in remote Australia 98 5.2.1 Current state of energy use in remote Australia 98 5.2.2 Potential and opportunities for solar energy supply 99 5.2.2.1 Location 100 5.2.2.2 Community needs * 100 5.2.2.3 Potential applications of renewable energy in agriculture in remote communities 101 5.2.2.4 Cost of solar technology 101 5.2.2.5 Increasing solar energy supply penetration 102 5.2.2.Ó Growth in experience and capacity 103 52.2.1 Storage and integration 103 5.2.3 Challenges for solar energy supply 104 5.3 Case studies from inland remote Australia 106 5.3.1 Description of Alice Springs and Lajamanu 106 5.3.2 Current state of energy supply mix in case studies 106 5.3.3 Opportunities and challenges for renewable energy in the case study locations 106 5.4 Discussion 108 5.5 Conclusion 110 6. Opportunities of adopting renewable energy for the nursery industry in Australia 115 Guangnan Chen, Erik Schmidt, TekMaraseni, Jochen Bundschuh, Thomas Banhazi Diogenes L. Antille 6.1 Introduction 115 6.2 Energy use in nursery 115 6.2.1 Energy audits and assessments 115 6.2.2 Case studies of nursery energy use in Australia 116 6.3 Opportunities of adopting alternative energy sources 120 6.3.1 Opportunities of adopting solar energy 120 6.3.2 Opportunities of adopting wind energy 120 6.3.3 Opportunities of adopting bioenergy 120 6.4 Development of online calculator for alternative energy sources 121 6.5 Casestudies 122 6.5.1 Solar energy generation 122 6.5.2 Wind energy generation 123 6.6 Conclusion 124 7. Fundamentals of solar energy 127 Maciej Klein, Kamil Łapiński, Katarzyna Siuzdak Adam Cenian 7.1 Introduction 127 7.1.1 Solar energy resources and potentials 127 7.1.2 Solar radiation and maps 127 7.2 Photovoltaic effect ֊ principle and operating mechanism of solar cells 130 7.2.1 History of photovoltaic effect discovery and PV-cell development 130 7.2.1.1 First generation silicon-based solar cells 130 7.2.1.2 Second generation solar cells 134 7.2.1.3 Third generation solar cell 135 7.2.2 Main characteristics of solar cells 137 7.3 System design: PV direct, grid-tied, stand-alone, grid-tied with battery backup, solar thermal - PVT 138 7.3.1 On-grid and off-grid systems and their applications 139 7.3.2 PVT systems and their application 140 7.4 Storage: batteries, capacitors and supercapacitors, operation principle, new development (graphen etc.) 142 7.4.1 Batteries 143 7.4.1.1 Primary batteries 143 7.4.1.2 Secondary (rechargeable) batteries 143 7.4.2 Capacitors and supercapacitors 144 7.4.2.1 Supercapacitor construction 146 7.4.2.2 Supercapacitor vs. other energy storage devices 148 8. Renewable energy technologies for greenhouses in semi-arid climates 153 Francisco Javier Cabrera, Jorge Antonio Sánchez-Molina, Guillermo Zaragoza, Manuel Perez-Garcia Francisco Rodriguez-Diaz 8.1 Introduction 153 8.2 Greenhouses in semi-arid climates 155 8.3 Overview of energy demands in greenhouses 156 8.3.1 Greenhouse heating and cooling loads 158 8.3.2 Greenhouse electricity requirements 160 8.4 Renewable energies applicable to greenhouses 162 8.4.1 Wind energy 163 8.4.2 Low and medium temperature solar thermal energy 163 8.4.2.1 Components and configurations of solar thermal energy systems for greenhouses 164 8.4.2.2 Experience in the use of solar thermal energy in greenhouses 166 8.4.3 PV solar energy 167 8.4.3.1 Components and configurations of PV systems for greenhouses 168 8.4.3.2 Experience in the use of PV energy in greenhouses 171 8.4.3.3 Sizing of PV systems for greenhouse applications 173 8.4.4 Geothermal energy 174 8.4.5 Biomass 175 8.4.5.1 Biomass preparation 175 8.4.5.2 Biomass heaters 177 8.5 Energy savings from crop growth control in greenhouses using optimal controllers 178 8.6 Conclusions 182 9. Solar photocatalytic disinfection of water for reuse in irrigation 195 Pilar Femández-Ibáñez, María Inmaculada Polo֊López, Տեէօ Malato, Alba Ruiz֊Aguirre Guillermo Zaragoza 9.1 Introduction 195 9.2 Compound parabolic collectors for water disinfection 196 9.3 Solar water disinfection (SODIS) 197 9.4 Advanced oxidation processes (AOPs) 198 9.4.1 Photocatalysis with titanium dioxide (TiCVsolar) 198 9.4.2 Photocatalysis with the photo-Fenton process (Fe/F^CVsolar) 200 9.4.3 Solar-driven process with Ւ1շՕշ 202 9.5 Disinfection of wastewater effluents by solar treatments 203 9.6 Improvements in water disinfection by membrane distillation pretreatment 205 9.7 Concluding remarks and future perspectives 208 Solar PV for water pumping and Irrigation 213 Istvän Patay, Istvän Seres Jochen Bundschuh 10.1 Introduction 213 10.2 Energy demand of water pumping 215 10.2.1 The energetic process of irrigation '216 10.2.2 Energetics of the irrigation equipment 217 10.3 Energy demand of irrigation methods 219 10.3.1 Sprinkler irrigation 219 10.3.2 Drip irrigation 220 10.4 Electric water pumps for water supply and irrigation 221 10,4.1 Types of solar pumps 221 10,4.2 Characteristics of pumps 222 10.4.3 Solar PV pumping stations 223 10.5 Solar PV panels for pumping 225 10.6 Design of solar PV-based irrigation 226 10.6.1 Theory 226 10.6.2 Application 228 10.7 Solar water pumping in Economic comparison with diesel- and grid electricity-powered pumping 229 10.8 Case studies 231 10.8.1 USA 231 10.8.2 India 231 10.8.3 Morocco 232 10.9 Conclusions 232 Solar drying 235 Om Prakash, Anil Kumar Atul Sharma 11.1 Introduction 235 11.1.1 Importance of renewable energy 236 11.2 Basics of drying 237 11.2.1 Moisture content 237 11.2.2 Moisture content evaluation 237 11.2.3 Theory of drying 237 11.2.3.1 Thin-layer drying 237 11.2.3.2 Thick-bed drying 238 11.3 Selection of solar dryers for the product 240 11.4 Types of solar dryers 240 11.4.1 Natural solar dryers 241 11.4.2 Direct solar dryers 243 11.4.3 Indirect solar dryer 246 11.4,4 Mixed solar dryer 247 11.5 Testing of solar dryer 247 11.5.1 No-load testing of the solar dryer 247 11.5.2 Testing the solar dryer under load conditions 249 11.5.2.1 Heat collection efficiency 249 11.5.2.2 Pick-up efficiency 249 11.5.2.3 Drying efficiency 249 11.5.2.4 Drying rate 250 11.6 Energy analysis 250 11.6.1 Embodied energy 250 11.6.2 Embodied energy for materials 250 11.6.3 Energy payback time 251 11.6.4 Analysis of EPBT of solar dryers 251 11.6.4.1 Cabinet dryer 251 11.6.4.2 Modified greenhouse dryer 252 11.6.5 CO2 emissions 254 11.7 Impact of solar drying on product quality 255 11.8 Concluding remarks 255 12. Small-scale wind power energy systems for use in agriculture and similar applications 259 Wojciech Miqskowski, Krzysztof Nalepa, Pawet Pietkiewicz Janusz Piechocki 12.1 Introduction 259 12.2 Assessment of wind parameters for the purpose of wind turbine location 259 12.2.1 Key parameters of wind as a source of energy 259 12.2.2 Maximizing the potential of wind power on local ground 265 12.3 Types of wind turbines 266 12.3.1 Classification of wind turbines 267 12.3.1.1 Classification based on capacity 267 12.3.1.2 Classification based on size 267 12.3.1.3 Classification based on axis of rotation 267 12.3.1.4 Classification based on other criteria 267 12.4 Horizontal-axis wind turbines (HAWTs) 267 12.4.1 Basic working principle of HAWTs 270 12.4.2 Examples of structural solutions 270 12.4.2.1 Structural solutions with three-bladed rotors 270 12.4.2.2 Single- and twin-bladed wind turbines 273 12.4.2.3 Multi-bladed wind towers 273 12.4.2.4 Diffuser-augmented wind turbines 273 12.4.2.5 Energy Ball wind turbines 274 12.5 Vertical-axis wind turbines (VAWTs) 274 12.5.1 Structural solutions 276 12.5.1.1 Wind-powered generators that rely on the Savonius turbine 276 12.5.1.2 H-rotor turbines 276 12.5.1.3 Drum-rotor turbines 277 12.6 Strengths and weaknesses of HAWTs and VAWTs 278 12.6.1 Strengths and weaknesses of horizontal-axis wind turbines 278 12.6.2 Strengths and weaknesses of vertical-axis wind turbines 278 12.7 Applications of wind turbines 279 12.7.1 Possible applications of wind micro-turbines 279 12.7.2 The use of small-scale wind turbines in rural areas 279 12.8 Wind energy solutions for households 280 12.8.1 Solution 1 - Conversion of wind energy to electricity 281 12.8.2 Solution 2 - Conversion of wind energy to heat 283 12.8.3 Solution 3 - Conversion of wind energy to electricity with excess energy storage in the form of hydrogen 283 12.8.4 Solution 4 - Conversion of wind energy to electricity with excess energy storage in the form of compressed air 284 12.8.5 Solutions 5 and 6 - Conversion of wind energy to mechanical energy 285 12.9 Conclusions 286 Windmills for water pumping, irrigation and drainage 289 Istvan Patay Norbert Schrempf 13.1 Introduction 289 13.2 Wind technologies for water pumping 289 13.2.1 Direct water pumping 289 13.2.2 Characteristics of windmills 290 13.2.3 Wind electric pumping 293 13.2.4 Solar-wind electric pump system 296 13.3 Applications 297 13.3.1 Water supply of fish pond 297 13.3.2 Water tank capacity 298 Lakes as a heat source for heat pumps ֊ a model study to determine the ecological impact of summer heat transfer 301 Renata Brzozowska, Maciej Neugebauer Janusz Piechocki 14.1 Introduction 301 14.2 Heat pumps 302 14.2.1 Theoretical basis of operation of the heat pump 302 14.2.2 Construction of compressor heat pumps 302 14.2.3 The ideal thermodynamic cycle of the heat pump compressor 303 14.2.4 Working media 305 14.2.5 Lower heat source 305 14.2.5.1 Atmospheric air 306 14.2.5.2 Solar energy 306 14.2.5.3 Waste heat 306 14.2.5.4 Ground 306 14.2.5.5 Water 307 14.2.6 Examples of heat pump installations that use surface water as a heat source 311 14.2.6.1 Using heat pumps for agriculture 311 14.2.6.2 Examples of the use of heat pumps in agriculture using surface water as a heat source 312 14.2.6.3 Stockholm, Sweden 314 14.2.6.4 Xinghai, China 315 14.2.6.5 Helsinki, Finland 316 14.2.6.6 Paris, France 317 14.2.6.7 Zurich, Switzerland 317 14.2.6.8 Gródek, Poland 318 14.3 Lake characteristics and anthropogenic pressure of heat pumps on lakes 319 14.3.1 The physical properties of water and its influence on lakes’ thermal regimes 320 14.3.2 Morphometric factors controlling lakes 321 14.3.2.1 Mean depth 321 14.3.2.2 Maximum effective length and width of lake 321 14.3.2.3 Relative depth 322 14.3.2.4 Depth index 322 14.3.3 The temperature influence on in-lake processes 323 14.3.4 Lake modeling 327 14.3.4.1 Comparison 334 14.4 Calculations 335 14.4.1 Preliminary assumptions 335 14.4.2 Calculation of the total amount of energy stored in the lake 335 14.4.3 Receiving heat in winter- increasing the thickness ofthe ice layer 339 14.4.4 The introduction of heat into the lake in the summer 339 14.5 Conclusions 342 Subject index Book series page 349 361 The agri-iood chain consumes about one third of the world's energy production with about 12% of it for crop production and nearly 80% for processing, distribution, retail, preparation and cooking. The agri-food chain also accounts for 80-90% of total global freshwater use where 70% alone is for irrigation. Additionally, on a global scale, freshwater production consumes nearly 15% of the entire energy production. It can therefore be argued that making agriculture and the agri-food supply chain independent from fossil fuel use has a huge potential to contribute to global food security and climate protection not only for the next decades but also for the coming century. Provision of secure, accessible and environmentally sustainable supplies of water, energy and food must thus be a priority. One of the major objectives of the world's scientists, farmers, decisions makers and industrialists is to overcome the present dependence on fossil fuels in the agro-food sector. This dependency increases the volatility of food prices and affects economic access to sustenance. This book provides a critical review of recent developments in solar, wind and geothermal energy applications in agriculture and the agro-food sector such as processing, distribution, retail, preparation and cooking.
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genre_facet	Aufsatzsammlung
id	DE-604.BV044423443
illustrated	Illustrated
indexdate	2024-10-14T14:12:24Z
institution	BVB
isbn	9781138029705
language	English
oai_aleph_id	oai:aleph.bib-bvb.de:BVB01-029824996
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owner	DE-384 DE-11
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physical	xliv, 359 Seiten Illustrationen, Diagramme, Karten
publishDate	2017
publishDateSearch	2017
publishDateSort	2017
publisher	CRC Press
record_format	marc
series	Sustainable Energy Developments
series2	Sustainable Energy Developments
spelling	Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture editors, Jochen Bundschuh, Guangnan Chen, D. Chandrasekharam, Janusz Piechocki London CRC Press [2017] © 2017 xliv, 359 Seiten Illustrationen, Diagramme, Karten txt rdacontent n rdamedia nc rdacarrier Sustainable Energy Developments Volume 13 Aquakultur (DE-588)4112555-1 gnd rswk-swf Landwirtschaft (DE-588)4034402-2 gnd rswk-swf Windenergie (DE-588)4079329-1 gnd rswk-swf Geothermik (DE-588)4020285-9 gnd rswk-swf (DE-588)4143413-4 Aufsatzsammlung gnd-content Windenergie (DE-588)4079329-1 s Geothermik (DE-588)4020285-9 s Landwirtschaft (DE-588)4034402-2 s Aquakultur (DE-588)4112555-1 s DE-604 Bundschuh, Jochen 1960- (DE-588)1064353835 edt Chen, Guangnan edt Chandrasekharam, Dornadula 1948- (DE-588)136584454 edt Piechocki, Janusz (DE-588)1067813284 edt Erscheint auch als Online-Ausgabe, eBook 978-1-315-15896-9 Sustainable Energy Developments Volume 13 (DE-604)BV040312835 13 Digitalisierung UB Augsburg - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029824996&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis Digitalisierung UB Augsburg - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029824996&sequence=000002&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA Klappentext
spellingShingle	Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture Sustainable Energy Developments Aquakultur (DE-588)4112555-1 gnd Landwirtschaft (DE-588)4034402-2 gnd Windenergie (DE-588)4079329-1 gnd Geothermik (DE-588)4020285-9 gnd
subject_GND	(DE-588)4112555-1 (DE-588)4034402-2 (DE-588)4079329-1 (DE-588)4020285-9 (DE-588)4143413-4
title	Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture
title_auth	Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture
title_exact_search	Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture
title_full	Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture editors, Jochen Bundschuh, Guangnan Chen, D. Chandrasekharam, Janusz Piechocki
title_fullStr	Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture editors, Jochen Bundschuh, Guangnan Chen, D. Chandrasekharam, Janusz Piechocki
title_full_unstemmed	Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture editors, Jochen Bundschuh, Guangnan Chen, D. Chandrasekharam, Janusz Piechocki
title_short	Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture
title_sort	geothermal wind and solar energy applications in agriculture and aquaculture
topic	Aquakultur (DE-588)4112555-1 gnd Landwirtschaft (DE-588)4034402-2 gnd Windenergie (DE-588)4079329-1 gnd Geothermik (DE-588)4020285-9 gnd
topic_facet	Aquakultur Landwirtschaft Windenergie Geothermik Aufsatzsammlung
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029824996&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029824996&sequence=000002&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA
volume_link	(DE-604)BV040312835
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