Engineered Nanomaterials for Sustainable Agricultural Production, Soil Improvement and Stress Management highlights the latest advances in applying this important technology within agriculture sectors for sustainable growth, production and protection. The book explores various smart engineered nanomaterials which are now being used as an important tool for improving growth and productivity of crops facing abiotic stresses, improving the health of the soil in which those crops are growing, and addressing stresses once the plant begins to produce food yield. The book includes insights into the use of nanoparticles as bactericides, fungicides and nanofertilizers. In addition, the book includes an international representation of authors who have crafted chapters with clarity, reviewing up-to-date literature with lucid illustrations. It will be an important resource for researchers, nanobiotechnologists, agriculturists and horticulturists who need a comprehensive reference guide. - Broadens the role of smart engineered (carbon, fullerene or metal based, and more) nanomaterials, with up-to-date literature and practical illustrations - Equips readers with information on a number of morpho-physiological, biochemical, molecular phenomenon, and smart agricultural production - Enriches our understanding of various smart crop plants resilient to abiotic and biotic stresses in terms of nanomaterials exposure
Nanotechnology in Sustainable Agriculture presents applications of nanobiotechnology for eco-friendly agriculture practices. Implementing sustainable agriculture techniques is a crucial component in meeting projected global food demands while minimising toxic waste in the environment. Nano-technological tools – including nanoparticles, nanocapsules, nanotubes and nanomolecules – offer sustainable options to modernise agriculture systems. Written by nanotechnology experts, this book outlines how nano-formulations can improve yield without reliance on chemecial pesticides and reduce nutrient losses in fertilization. It reveals how nanotools are used for rapid disease diagnostics, in treating plant diseases and enhancing the capacity for plants to absorb nutrients. Features: Combines nanotechnology and agronomy presenting applications for improving plant performance and yields. Reveals nanotechnology-based products used for the soil and plant health management which mitigate climate change. Discusses roles of microbial endophytes, heavy metal nanoparticles and environment health, nano-nutrients, phytochemicals, green bioengineering and plant health. This book appeals to professionals working in the agriculture and food industry, as well as agricultural scientists and researchers in nanotechnology and agronomy.
This book looks at the interaction between plants and nanomaterials/nanocomposites, and their effects ecology, the food chain and human health. It focuses on nanomaterials/nanocomposites phytotoxicity, which is an important precondition to promote the application of nanotechnology and to avoid the potential ecological risks. It describes the influencing factors of nanotoxicity of nanomaterials and the mechanisms of these toxic effects and defense mechanisms in plants. The chapters in this book are written by internationally renowned researchers and professionals and provides exciting and remarkable information (on the above-mentioned topics) to the scientist, researcher and student working field of plant biology, agricultural science, nanobiotechnology, plant biochemistry, plant physiology, plant biotechnology and many other interdisciplinary subjects.
Biostimulants (a diverse class of compounds including substances or microorganisms) are helpful in sustainable plants growth and development. They accelerate plant growth, yield, and chemical composition even under unfavorable conditions. The main biostimulants are nitrogen-containing compounds, humic materials, some specific compounds released by microbes, plants, and animals, various seaweed extracts, bio-based nanomaterials, phosphite, silicon, and so on. Additionally, new generation products and bioproducts are being developed for sustainable plant growth and protection. Some research works in the area of biotechnology and nanobiotechnology have shown improved sustainable plant growth and production. The protective roles of biostimulants are varied depends on the compound and plant species. Exposure of biostimulants have shown accelerated plants growth and developmental processes for instance, manage stomatal conductance and rate of transpiration, and increase rate of photosynthesis etc. They also increased crop plants immune systems against the adverse situation. Thus, use of innovations of new generation biostimulants also enhance plant production systems, through a significant reduction of synthetic chemicals such as pesticides and fertilizers. Moreover, bioinoculants commercial products obtained from seaweed extract, humic acids, amino acids, fulvic acids, and some microbial inoculants have shown their potential role in adventitious root induction in plants. Microbial inoculants or microbial-based biostimulants, as a promising and eco-friendly technology, can be widely used to address environmental concerns and fulfill the need for developing sustainable or modern agriculture practices. They have great potential to elicit plant tolerance to various climate change-related stresses and thus enhance plant growth and overall performance-related features. However, for successful implementation biostimulants-based agriculture in the field under changing climate conditions, an understanding of plant functions and biostimulants interaction or action mechanisms coping with various abiotic as well as biotic stresses at the physicochemical, metabolic, and molecular levels is required. Mycorrhizae are beneficial fungi that form symbiotic associations with plants and aid in plant development, disease resistance, and soil health is well established. Similarly, phyllospheric microbiome are known to possess different plant growth promotion attributes like nitrogen fixation, phosphate solubilization, biocontrol activity, and increase plant resistance towards abiotic stresses. The plant growth promotion traits possessed by these phyllospheric microbiota can be judiciously harbored for phyllospheric and rhizospheric engineering. The engineered phyllospheric and rhizospheric microbiome can increase the plant growth and productivity, thereby, can act as a driving force for increasing the agricultural production in a sustainable manner. Taken together, this book aims to contribute to the recent understanding associated with the various role and application of biostimulants on different plant for their sustainable growth and management. - Discusses our current understanding of, and advances in, biostimulants, along with their application in plants growth performance and overall management - Explores new techniques, new generation products, and bioproducts - Highlights the role of seaweed extract, humic acids, protein hydrolysates, amino acids, melatonin, paramylon, fulvic acids, microbial inoculants (phyllospheric and rhizospheric), and more
Nanotechnology research and its application in agriculture has become a major focus in recent years. Nanoformulations offer the possibility to develop more efficient and less damaging agrochemicals in the environment. Smart delivery systems for nanosensors, molecules that can help to detect biotic or abiotic stresses before they can affect production, are being developed and applied. Nanotechnology also provides new techniques for genetic manipulation and plant breeding. The use of nanoformulations in agriculture is increasingly being used to enhance food values, reduce agricultural inputs, improve nutrient contents and create a longer shelf life for many products. Nanotechnology is also being applied to many aspects of food security, disease treatment, new tools for pathogen detection, effective delivery systems and packaging materials. All of these applications are supposed to assist in addressing the needs of a growing population, and help in mitigating the effects of climate change and other ecological disturbances. This book highlights new applications of these nanoforms in the field of agricultural science, written by an international team of experts from across this broad discipline. It is essential reading for graduate students, researchers and practitioners involved in the application of nanotechnology in agriculture.
In the evolving world of industrial materials, conventional choices have proved to be insufficient to meet the demands of contemporary applications. With the introduction of Nanoscience and Nanotechnology, groundbreaking synthesis approaches are crafting nanocomposites with unprecedented versatility. Smart and Sustainable Applications of Nanocomposites delves into this research, exploring the bioinspired synthesis of nanocomposites and their multi-dimensional applications across diverse industries. This book addresses the escalating challenges faced by the nano-industry, such as the widening application window requiring additional properties like high modulus, flame retardation, UV resistance, and more. The book champions the development of environmentally friendly nanocomposites, ushering in the next generation of nanomaterials by reinforcing fibers, whiskers, or nano clays. Unique substitutes like ceramic, agricultural waste, and polymer–layered silicate nanocomposites are thoroughly examined for their exceptional physical, chemical, and physicochemical properties. From triobiological applications to the synthesis of bio-nanocoating, the book spans an array of subjects, each chapter revealing the potential applications of nanotechnology and nanocoatings in diverse fields. It highlights the ethical and environmental implications of this burgeoning technology, making it a crucial resource for students, researchers, academicians, and industry professionals.
The agricultural food system needs to provide access to enough healthy and affordable food for the growing population and mitigate its impact on the planet for future generations. Emerging technologies can help farmers increase yields.The book presents theoretical and applied aspects of nanotechnology and biotechnology. It also includes topics on management and food security.
Essential Minerals in Plant-Soil Systems: Coordination, Signaling and Interaction Under Adverse Conditions is the first book to encompass these key aspects of plant science, biochemistry, soil science and fertilizer development in a single volume. Describing the micro- and macronutrients in the plant-soil system with the help of suitable illustrations, the book connects all the pieces enabling comprehensive and connected understanding. Terrestrial plants are sessile in nature. They face various adverse environmental conditions including soil nutrient-deficiency signals, which influence overall plant growth and development. Some of the essential nutrients are unreachable to roots due to their low solubility and relative immobilization. Thus, the soil-plant system has evolved signaling, communication and coordination responses for survival under multiple adverse situations. By evolving highly sophisticated mechanisms at the cellular as well as whole-plant scale, these plants have developed ways to co-regulate these stresses in order to maintain homeostasis. Essential Minerals in Plant-Soil Systems covers recent advances in the understanding of how plants coordinate the acquisition, transport, signaling, and interaction, cross-talks between macro- and micro-nutrients in adverse environmental situations. These points are key to understanding the significance of essential, as well as beneficial, elements for sustainable plant growth and production. This book is a valuable reference for those putting research into practice in addressing stress situations, as well as providing important foundational insights for further research. - Provides a comprehensive overview of micro- and macronutrients and their interaction with phytohormones under stress conditions - Explores proteomic and genomic research into deficiencies and toxicities in plant systems - Highlights the use of nanobiotechnology for controlled release of micro- and macronutrients in the plant-soil systems