Plant Factory Basics, Applications and Advances
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Plant Factory Basics, Applications and Advances
Masabni, Joseph G.; Kozai, Toyoki; Niu, Genhua
Elsevier Science & Technology
11/2021
462
Mole
Inglês
9780323851527
15 a 20 dias
880
Descrição não disponível.
PART 1. Introduction
1. Why plant factories with artificial lighting (PFALs) are necessary
2. Terms related to PFALs
3. Role and characteristics of PFALs
4. Contribution of PFALs to the Sustainable Development Goals (SDGs) and Beyond
PART 2. Basics
5. Photonmetric quantities and their application
6. LED product terminology and performance description of LED luminaires
7. Photon efficacy in horticulture: turning LED packages into LED luminaires
8. Balances and use efficiencies of CO2, water and energy
9. Hydroponics
10. Aquaponics
11. Plant responses to environments
PART 3. Applications
12. Productivity: Definition and application
13. How to integrate and optimize productivity
14. Emerging economics and profitability of PFALs
15. Business models and cost performance of downtown mini-plant factories
16. Indoor production of tomatoes
SECTION 4. Advanced Research in PFALs and Indoor Farms
17. Toward an optimal spectrum for photosynthesis and plant morphology in LED-based crop cultivation
18. Indoor lighting effects on plant nutritional compounds and mineral elements
19. Indoor Production of Ornamental Seedlings, Vegetable Transplants, and Microgreens
20. Molecular breeding of miraculin-accumulating tomatoes with suitable traits for cultivation in PFALs and the optimization of cultivation methods
21. Environmental control of PFAL
22. Human-Centered Perspective on Urban Agriculture
23. Towards commercial production of head vegetables in plant factories with artificial lighting (PFALs)
24. Concluding remarks
1. Why plant factories with artificial lighting (PFALs) are necessary
2. Terms related to PFALs
3. Role and characteristics of PFALs
4. Contribution of PFALs to the Sustainable Development Goals (SDGs) and Beyond
PART 2. Basics
5. Photonmetric quantities and their application
6. LED product terminology and performance description of LED luminaires
7. Photon efficacy in horticulture: turning LED packages into LED luminaires
8. Balances and use efficiencies of CO2, water and energy
9. Hydroponics
10. Aquaponics
11. Plant responses to environments
PART 3. Applications
12. Productivity: Definition and application
13. How to integrate and optimize productivity
14. Emerging economics and profitability of PFALs
15. Business models and cost performance of downtown mini-plant factories
16. Indoor production of tomatoes
SECTION 4. Advanced Research in PFALs and Indoor Farms
17. Toward an optimal spectrum for photosynthesis and plant morphology in LED-based crop cultivation
18. Indoor lighting effects on plant nutritional compounds and mineral elements
19. Indoor Production of Ornamental Seedlings, Vegetable Transplants, and Microgreens
20. Molecular breeding of miraculin-accumulating tomatoes with suitable traits for cultivation in PFALs and the optimization of cultivation methods
21. Environmental control of PFAL
22. Human-Centered Perspective on Urban Agriculture
23. Towards commercial production of head vegetables in plant factories with artificial lighting (PFALs)
24. Concluding remarks
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
a-Tocopherols; Aeroponics; Air velocity; Airflow distribution; Anthocyanins; Aquaculture; Aquaponics; Artificial light; Blue light; Blue; Bolting; Business administration sheet; Cabbage; Chinese cabbage; CO2 enrichment; Commonality; Consumption; Controllability; Controlled environment agriculture; Correlation; Cost-benefit analysis; Crossbreeding; Cultivation space; Current droop; Daily light integral; Diversity; Economics of markets; Energy balance; Energy; Environmental, social, and corporate governance (ESG)Plant-derived biodegradable plastics; Evidence-based data; Far-red light; Far-red; Fish stocking density; Fixed assets; Floriculture transplants; Folate; Food; Fruiting crops; Green light; Green; Head lettuce; Head vegetables; Health promotion; Horticulture therapy; Humidity control; HVAC optimization; Hydroponic system; Hydroponics; Ideal PFALs; Indoor farm; Indoor farming; Indoor growing module; Initial investment; Integrated productivity; Irradiation; Land use; Leafy greens; LED lamp; LED light source; LED luminaire; LED module; LED package; LED performance sheet; LEDs; Light conditions; Light emitting diode; Light environment; Light-emitting diode; Lighting module; Lighting system; Liners; Man-hour; Mass balance; Methodology; Microgreens; Miraculin-accumulating tomato; Molecular breeding; Morphology; Net photosynthetic rate; Nutrient film technique; Nutrient management; Nutrient solution formula; Observability; Operational efficiency; Optimization of growth conditions in PFALs; PFAL (Plant factory with artificial lighting)Plant factory; PFAL; Phenolic compounds; Photon flux density; Photon spectrum; Photonmetry; Photons; Photosynthesis; Photosynthetic photon flux density; Physiological response; Plant factory with artificial lighting (PFAL)Plant production; Plant temperature; Predictability; Preventive medicine; Productivity; Profitability; Radiometric quantities; Recombinant protein; Red; Relaxation effects; Reproducibility; Resource use efficiency; ROI; Root vegetable; Sensitivity analysis; SI units; Slectric energy; Sole-source lighting; Space farming; Spectrum; Sustainability; Sustainable development goals (SDGs)Sustainable food production; Sustainable nature therapy; Thermal droop; Tipburn; Traceability; Translocation; Transpiration rate; Ultraviolet; Urban agriculture; Urban area; Urban green revolution; Urban green space; Urban sustainability; Vapor pressure deficit; Vegetable transplants; Vertical farm; Vitamin C; Well-being
PART 1. Introduction
1. Why plant factories with artificial lighting (PFALs) are necessary
2. Terms related to PFALs
3. Role and characteristics of PFALs
4. Contribution of PFALs to the Sustainable Development Goals (SDGs) and Beyond
PART 2. Basics
5. Photonmetric quantities and their application
6. LED product terminology and performance description of LED luminaires
7. Photon efficacy in horticulture: turning LED packages into LED luminaires
8. Balances and use efficiencies of CO2, water and energy
9. Hydroponics
10. Aquaponics
11. Plant responses to environments
PART 3. Applications
12. Productivity: Definition and application
13. How to integrate and optimize productivity
14. Emerging economics and profitability of PFALs
15. Business models and cost performance of downtown mini-plant factories
16. Indoor production of tomatoes
SECTION 4. Advanced Research in PFALs and Indoor Farms
17. Toward an optimal spectrum for photosynthesis and plant morphology in LED-based crop cultivation
18. Indoor lighting effects on plant nutritional compounds and mineral elements
19. Indoor Production of Ornamental Seedlings, Vegetable Transplants, and Microgreens
20. Molecular breeding of miraculin-accumulating tomatoes with suitable traits for cultivation in PFALs and the optimization of cultivation methods
21. Environmental control of PFAL
22. Human-Centered Perspective on Urban Agriculture
23. Towards commercial production of head vegetables in plant factories with artificial lighting (PFALs)
24. Concluding remarks
1. Why plant factories with artificial lighting (PFALs) are necessary
2. Terms related to PFALs
3. Role and characteristics of PFALs
4. Contribution of PFALs to the Sustainable Development Goals (SDGs) and Beyond
PART 2. Basics
5. Photonmetric quantities and their application
6. LED product terminology and performance description of LED luminaires
7. Photon efficacy in horticulture: turning LED packages into LED luminaires
8. Balances and use efficiencies of CO2, water and energy
9. Hydroponics
10. Aquaponics
11. Plant responses to environments
PART 3. Applications
12. Productivity: Definition and application
13. How to integrate and optimize productivity
14. Emerging economics and profitability of PFALs
15. Business models and cost performance of downtown mini-plant factories
16. Indoor production of tomatoes
SECTION 4. Advanced Research in PFALs and Indoor Farms
17. Toward an optimal spectrum for photosynthesis and plant morphology in LED-based crop cultivation
18. Indoor lighting effects on plant nutritional compounds and mineral elements
19. Indoor Production of Ornamental Seedlings, Vegetable Transplants, and Microgreens
20. Molecular breeding of miraculin-accumulating tomatoes with suitable traits for cultivation in PFALs and the optimization of cultivation methods
21. Environmental control of PFAL
22. Human-Centered Perspective on Urban Agriculture
23. Towards commercial production of head vegetables in plant factories with artificial lighting (PFALs)
24. Concluding remarks
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
a-Tocopherols; Aeroponics; Air velocity; Airflow distribution; Anthocyanins; Aquaculture; Aquaponics; Artificial light; Blue light; Blue; Bolting; Business administration sheet; Cabbage; Chinese cabbage; CO2 enrichment; Commonality; Consumption; Controllability; Controlled environment agriculture; Correlation; Cost-benefit analysis; Crossbreeding; Cultivation space; Current droop; Daily light integral; Diversity; Economics of markets; Energy balance; Energy; Environmental, social, and corporate governance (ESG)Plant-derived biodegradable plastics; Evidence-based data; Far-red light; Far-red; Fish stocking density; Fixed assets; Floriculture transplants; Folate; Food; Fruiting crops; Green light; Green; Head lettuce; Head vegetables; Health promotion; Horticulture therapy; Humidity control; HVAC optimization; Hydroponic system; Hydroponics; Ideal PFALs; Indoor farm; Indoor farming; Indoor growing module; Initial investment; Integrated productivity; Irradiation; Land use; Leafy greens; LED lamp; LED light source; LED luminaire; LED module; LED package; LED performance sheet; LEDs; Light conditions; Light emitting diode; Light environment; Light-emitting diode; Lighting module; Lighting system; Liners; Man-hour; Mass balance; Methodology; Microgreens; Miraculin-accumulating tomato; Molecular breeding; Morphology; Net photosynthetic rate; Nutrient film technique; Nutrient management; Nutrient solution formula; Observability; Operational efficiency; Optimization of growth conditions in PFALs; PFAL (Plant factory with artificial lighting)Plant factory; PFAL; Phenolic compounds; Photon flux density; Photon spectrum; Photonmetry; Photons; Photosynthesis; Photosynthetic photon flux density; Physiological response; Plant factory with artificial lighting (PFAL)Plant production; Plant temperature; Predictability; Preventive medicine; Productivity; Profitability; Radiometric quantities; Recombinant protein; Red; Relaxation effects; Reproducibility; Resource use efficiency; ROI; Root vegetable; Sensitivity analysis; SI units; Slectric energy; Sole-source lighting; Space farming; Spectrum; Sustainability; Sustainable development goals (SDGs)Sustainable food production; Sustainable nature therapy; Thermal droop; Tipburn; Traceability; Translocation; Transpiration rate; Ultraviolet; Urban agriculture; Urban area; Urban green revolution; Urban green space; Urban sustainability; Vapor pressure deficit; Vegetable transplants; Vertical farm; Vitamin C; Well-being
