Biotic Stress Management of Crop Plants using Nanomaterials

Nanomaterials have diverse applications in plant biotic stress management, such as enzyme-mimicking nanoparticles, nano-pesticides, nano-fertilizers, and nanomaterials. They can be used for diagnostics, enzyme-mimicking, crop protection, and plant disease management. Synthetic strategies, properties, chemistry, and applications of nanomaterials are discussed.

Format: Hardback
Length: 196 pages
Publication date: 18 May 2023
Publisher: Taylor & Francis Ltd

Nanomaterials, with their remarkable properties and diverse applications, have emerged as a promising tool in the management of plant biotic stress. This comprehensive review explores the current research on nanomaterials and their versatile applications in addressing various challenges faced by crop plants.

Nanomaterials are being utilized as enzyme-mimicking nanoparticles, nano-pesticides, nano-fertilizers, and other innovative solutions to combat plant stress. These materials mimic the functions of natural enzymes, enhancing their activities and promoting plant growth.

One of the significant challenges crop plants face is the presence of pests and diseases. Nanomaterials offer promising solutions in the form of nano-pesticides and nano-fertilizers. These materials can be designed to target specific pests or diseases, reducing the use of harmful chemicals and minimizing environmental impact.

Diagnostics play a crucial role in identifying and managing plant stress. Nanomaterials, such as biosensors and imaging techniques, can provide rapid and accurate detection of plant stressors. This information can be used to develop targeted interventions and improve crop productivity.

Enzyme-mimicking nanoparticles are another area of research where nanomaterials are making significant contributions. These nanoparticles can mimic the activities of natural enzymes, enhancing their efficiency and promoting specific metabolic pathways. This has the potential to improve crop yields and reduce the need for chemical fertilizers.

Crop protection is another area where nanomaterials are being explored. Nanomaterials can be used to create coatings, films, or other protective barriers that protect plants from environmental stressors such as drought, heat, or pests. These materials can improve crop resilience and reduce crop losses.

In addition to their utility in plant biotic stress management, nanomaterials are also being investigated for their potential role in plant disease management. Nanomaterials can be designed to target specific pathogens or to enhance the plant's immune system, reducing the risk of disease outbreaks.

Several pertinent nanomaterials have been developed, including synthetic strategies, properties, chemistry, and applications. These materials offer a wide range of possibilities for improving crop productivity and addressing environmental challenges.

In conclusion, nanomaterials have the potential to revolutionize plant biotic stress management. Their versatile applications, from enzyme-mimicking nanoparticles to nano-pesticides and nano-fertilizers, offer promising solutions to address the challenges faced by crop plants. With continued research and development, nanomaterials will play an increasingly important role in improving crop yields, reducing environmental impact, and promoting sustainable agriculture.

Nanomaterials, with their remarkable properties and diverse applications, have emerged as a promising tool in the management of plant biotic stress. This comprehensive review explores the current research on nanomaterials and their versatile applications in addressing various challenges faced by crop plants.

Nanomaterials are being utilized as enzyme-mimicking nanoparticles, nano-pesticides, nano-fertilizers, and other innovative solutions to combat plant stress. These materials mimic the functions of natural enzymes, enhancing their activities and promoting plant growth.

One of the significant challenges crop plants face is the presence of pests and diseases. Nanomaterials offer promising solutions in the form of nano-pesticides and nano-fertilizers. These materials can be designed to target specific pests or diseases, reducing the use of harmful chemicals and minimizing environmental impact.

Diagnostics play a crucial role in identifying and managing plant stress. Nanomaterials, such as biosensors and imaging techniques, can provide rapid and accurate detection of plant stressors. This information can be used to develop targeted interventions and improve crop productivity.

Enzyme-mimicking nanoparticles are another area of research where nanomaterials are making significant contributions. These nanoparticles can mimic the activities of natural enzymes, enhancing their efficiency and promoting specific metabolic pathways. This has the potential to improve crop yields and reduce the need for chemical fertilizers.

Crop protection is another area where nanomaterials are being explored. Nanomaterials can be used to create coatings, films, or other protective barriers that protect plants from environmental stressors such as drought, heat, or pests. These materials can improve crop resilience and reduce crop losses.

In addition to their utility in plant biotic stress management, nanomaterials are also being investigated for their potential role in plant disease management. Nanomaterials can be designed to target specific pathogens or to enhance the plant's immune system, reducing the risk of disease outbreaks.

Several pertinent nanomaterials have been developed, including synthetic strategies, properties, chemistry, and applications. These materials offer a wide range of possibilities for improving crop productivity and addressing environmental challenges.

In conclusion, nanomaterials have the potential to revolutionize plant biotic stress management. Their versatile applications, from enzyme-mimicking nanoparticles to nano-pesticides and nano-fertilizers, offer promising solutions to address the challenges faced by crop plants. With continued research and development, nanomaterials will play an increasingly important role in improving crop yields, reducing environmental impact, and promoting sustainable agriculture.

Weight: 550g
Dimension: 234 x 156 (mm)
ISBN-13: 9781032344317