Silicon and Nano-silicon in Environmental Stress Management and Crop Quality Improvement
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Silicon and Nano-silicon in Environmental Stress Management and Crop Quality Improvement
Progress and Prospects
Etesami, Hassan; Pessarakli, Mohammad; Anwar Hossain, Mohammad; El-Ramady, Hassan; Fujita, Masayuki; Al Saeedi, Abdullah H.
Elsevier Science & Technology
04/2022
396
Mole
Inglês
9780323912259
15 a 20 dias
1090
Descrição não disponível.
1. Sources of silicon and nano-silicon in soil and plants
2. Silicon and nano-silicon: New frontiers of biostimulants for plant growth and stress amelioration
3. Silicon uptake, acquisition and accumulation in plants
4. Silicon bioavailability in relation to plant nutrition
5. Use of silicon and nano-silicon in agro-biotechnologies
6. The genetics of silicon accumulation by plants
7. Silicon-mediated modulations of genes and secondary metabolites in plants
8. Silicon-mediated salt stress tolerance in plants
9. Nano-silicon mediated salt stress tolerance in plants
10. Silicon and nano-silicon mediated drought and waterlogging stress tolerance in plants
11. Silicon and nano-silicon mediated heat stress tolerance in plants
12. Silicon and nano-silicon mediated cold stress tolerance in plants
13. Silicon and nano-silicon mediated heavy metal stress tolerance in plants
14. Silicon and nano-silicon mediated disease resistance in crop plants
15. Silicon and nano-silicon mediated nutrient deficiency tolerance in crop plants
16. Silicon as a plant defence against insect herbivory
17. Recent developments in nano-silicon mediated tolerance against herbivores
18. Interactive effects of silicon, nano-silicon and arbuscular mycorrhiza on the resistance of plants to various stresses
19. Biodissolution of silica by silicate solubilizing microorganisms in rhizosphere of plants
20. Silicon and nano-silicon in plant nutrition and crop quality
21. Effect of silicon and nano-silicon application on rice yield and quality
22. Biological impacts on silicon availability and cycling in agricultural plant-soil systems
23. Exogenous silicone-mediated plant growth and environmental stress tolerance in plants
24. Manipulation of silicon metabolism in plants for stress tolerance
25. Future research direction of silicon and nano-silicon in crop stress tolerance and crop quality improvements
2. Silicon and nano-silicon: New frontiers of biostimulants for plant growth and stress amelioration
3. Silicon uptake, acquisition and accumulation in plants
4. Silicon bioavailability in relation to plant nutrition
5. Use of silicon and nano-silicon in agro-biotechnologies
6. The genetics of silicon accumulation by plants
7. Silicon-mediated modulations of genes and secondary metabolites in plants
8. Silicon-mediated salt stress tolerance in plants
9. Nano-silicon mediated salt stress tolerance in plants
10. Silicon and nano-silicon mediated drought and waterlogging stress tolerance in plants
11. Silicon and nano-silicon mediated heat stress tolerance in plants
12. Silicon and nano-silicon mediated cold stress tolerance in plants
13. Silicon and nano-silicon mediated heavy metal stress tolerance in plants
14. Silicon and nano-silicon mediated disease resistance in crop plants
15. Silicon and nano-silicon mediated nutrient deficiency tolerance in crop plants
16. Silicon as a plant defence against insect herbivory
17. Recent developments in nano-silicon mediated tolerance against herbivores
18. Interactive effects of silicon, nano-silicon and arbuscular mycorrhiza on the resistance of plants to various stresses
19. Biodissolution of silica by silicate solubilizing microorganisms in rhizosphere of plants
20. Silicon and nano-silicon in plant nutrition and crop quality
21. Effect of silicon and nano-silicon application on rice yield and quality
22. Biological impacts on silicon availability and cycling in agricultural plant-soil systems
23. Exogenous silicone-mediated plant growth and environmental stress tolerance in plants
24. Manipulation of silicon metabolism in plants for stress tolerance
25. Future research direction of silicon and nano-silicon in crop stress tolerance and crop quality improvements
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Abiotic and biotic stress; Abiotic stress; Abiotic stress tolerance; Alpine meadows; Amendments; Antioxidant systems; Antioxidants; Arbuscular mycorrhiza; Beneficial element; Beneficial elements; Beneficial insects; Bioavailable Si; Biochemical changes; Biochemistry; Biogenic silica; Bioleaching; Biosilicification; Biostimulation; Biotic stress; Bioweathering; Cell wall modification; Cellular homeostasis; Cold acclimation; Cold signaling; Cold tolerance; Crop improvement; Crop yield; Disease resistance; Dose-response; Drought stress; Fertilizers; Flooding stress; Freezing stress; Gene expression; Grain yield (GY); Heat stress; Heavy metal stress; Herbivory; Hormesis; Hormonal control of cold stress; Hydrated amorphous silica; Hypoxia; Induced; Insect pest; Leaf apoplast; Leaf gas exchange; Mandibular wear; Mineralization; Morphological changes; Nano-fertilizers; Nano-silica; Nano-silicon; Nanoparticle; Nanoparticles; Nanoparticles (NPs); Nanosilica; Nanosilicon; Nanotechnology; Nutrient; Nutrient imbalances; Nutrient uptake; Nutrition; Nutrition role; Nutritional quality; Osmotic deregulations; Oxidative injury; Oxidative stress; Pathogens; Photosynthesis; Physiological changes; Phytohormone; Phytohormones; Plant community; Plant growth-promoting bacteria; Plant physiological aspects; ROS; Radial transport; Reactive oxygen species; Resistance; Rice enrichment; Salinity; Salinity stress; Secondary metabolite function; Secondary metabolites; Secondary metabolites assimilation; Si-bioavailability; SiNPs; Silica; Silica nanoparticles; Silicic acid; Silicon; Silicon and plant metabolism; Silicon cycling; Silicon distribution; Silicon extraction; Silicon fertilization; Silicon role; Silicon sources; Silicon transporter; Silicone
1. Sources of silicon and nano-silicon in soil and plants
2. Silicon and nano-silicon: New frontiers of biostimulants for plant growth and stress amelioration
3. Silicon uptake, acquisition and accumulation in plants
4. Silicon bioavailability in relation to plant nutrition
5. Use of silicon and nano-silicon in agro-biotechnologies
6. The genetics of silicon accumulation by plants
7. Silicon-mediated modulations of genes and secondary metabolites in plants
8. Silicon-mediated salt stress tolerance in plants
9. Nano-silicon mediated salt stress tolerance in plants
10. Silicon and nano-silicon mediated drought and waterlogging stress tolerance in plants
11. Silicon and nano-silicon mediated heat stress tolerance in plants
12. Silicon and nano-silicon mediated cold stress tolerance in plants
13. Silicon and nano-silicon mediated heavy metal stress tolerance in plants
14. Silicon and nano-silicon mediated disease resistance in crop plants
15. Silicon and nano-silicon mediated nutrient deficiency tolerance in crop plants
16. Silicon as a plant defence against insect herbivory
17. Recent developments in nano-silicon mediated tolerance against herbivores
18. Interactive effects of silicon, nano-silicon and arbuscular mycorrhiza on the resistance of plants to various stresses
19. Biodissolution of silica by silicate solubilizing microorganisms in rhizosphere of plants
20. Silicon and nano-silicon in plant nutrition and crop quality
21. Effect of silicon and nano-silicon application on rice yield and quality
22. Biological impacts on silicon availability and cycling in agricultural plant-soil systems
23. Exogenous silicone-mediated plant growth and environmental stress tolerance in plants
24. Manipulation of silicon metabolism in plants for stress tolerance
25. Future research direction of silicon and nano-silicon in crop stress tolerance and crop quality improvements
2. Silicon and nano-silicon: New frontiers of biostimulants for plant growth and stress amelioration
3. Silicon uptake, acquisition and accumulation in plants
4. Silicon bioavailability in relation to plant nutrition
5. Use of silicon and nano-silicon in agro-biotechnologies
6. The genetics of silicon accumulation by plants
7. Silicon-mediated modulations of genes and secondary metabolites in plants
8. Silicon-mediated salt stress tolerance in plants
9. Nano-silicon mediated salt stress tolerance in plants
10. Silicon and nano-silicon mediated drought and waterlogging stress tolerance in plants
11. Silicon and nano-silicon mediated heat stress tolerance in plants
12. Silicon and nano-silicon mediated cold stress tolerance in plants
13. Silicon and nano-silicon mediated heavy metal stress tolerance in plants
14. Silicon and nano-silicon mediated disease resistance in crop plants
15. Silicon and nano-silicon mediated nutrient deficiency tolerance in crop plants
16. Silicon as a plant defence against insect herbivory
17. Recent developments in nano-silicon mediated tolerance against herbivores
18. Interactive effects of silicon, nano-silicon and arbuscular mycorrhiza on the resistance of plants to various stresses
19. Biodissolution of silica by silicate solubilizing microorganisms in rhizosphere of plants
20. Silicon and nano-silicon in plant nutrition and crop quality
21. Effect of silicon and nano-silicon application on rice yield and quality
22. Biological impacts on silicon availability and cycling in agricultural plant-soil systems
23. Exogenous silicone-mediated plant growth and environmental stress tolerance in plants
24. Manipulation of silicon metabolism in plants for stress tolerance
25. Future research direction of silicon and nano-silicon in crop stress tolerance and crop quality improvements
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Abiotic and biotic stress; Abiotic stress; Abiotic stress tolerance; Alpine meadows; Amendments; Antioxidant systems; Antioxidants; Arbuscular mycorrhiza; Beneficial element; Beneficial elements; Beneficial insects; Bioavailable Si; Biochemical changes; Biochemistry; Biogenic silica; Bioleaching; Biosilicification; Biostimulation; Biotic stress; Bioweathering; Cell wall modification; Cellular homeostasis; Cold acclimation; Cold signaling; Cold tolerance; Crop improvement; Crop yield; Disease resistance; Dose-response; Drought stress; Fertilizers; Flooding stress; Freezing stress; Gene expression; Grain yield (GY); Heat stress; Heavy metal stress; Herbivory; Hormesis; Hormonal control of cold stress; Hydrated amorphous silica; Hypoxia; Induced; Insect pest; Leaf apoplast; Leaf gas exchange; Mandibular wear; Mineralization; Morphological changes; Nano-fertilizers; Nano-silica; Nano-silicon; Nanoparticle; Nanoparticles; Nanoparticles (NPs); Nanosilica; Nanosilicon; Nanotechnology; Nutrient; Nutrient imbalances; Nutrient uptake; Nutrition; Nutrition role; Nutritional quality; Osmotic deregulations; Oxidative injury; Oxidative stress; Pathogens; Photosynthesis; Physiological changes; Phytohormone; Phytohormones; Plant community; Plant growth-promoting bacteria; Plant physiological aspects; ROS; Radial transport; Reactive oxygen species; Resistance; Rice enrichment; Salinity; Salinity stress; Secondary metabolite function; Secondary metabolites; Secondary metabolites assimilation; Si-bioavailability; SiNPs; Silica; Silica nanoparticles; Silicic acid; Silicon; Silicon and plant metabolism; Silicon cycling; Silicon distribution; Silicon extraction; Silicon fertilization; Silicon role; Silicon sources; Silicon transporter; Silicone
