Disha Mishra – författare

Nanotechnology and Nanomaterials in the Agri-Food Industries: Smart Nanoarchitectures, Technologies, Challenges, and Applications brings together the latest advances in the utilization of advances nanotechnology, nanoarchitectures, and nanomaterials in the agricultural and food sectors. The book begins by discussing recent trends towards sustainable synthesis and application, covering green nanomaterials and biodegradable nanomaterials and composites. Subsequent chapters focus on key application areas of engineered nanomaterials in both agriculture and food processing, such as crop production and protection, delivery vehicles, detection of contaminants, nanobionic and genetic engineering in plants, active food packaging and preservation, enhanced food formulations and nutrients, nanoscale additives for freshness, and nanosensors.

This is followed by a section that addresses key challenges relating to the application of nanostructures and nanodevices in these sectors, including global market considerations, health and environmental concerns, and intellectual property and socio-economic issues. Finally, policy implications and future perspective for the field are reviewed in detail.

Presents cutting-edge applications of nanotechnology across agriculture and food processing Highlights the latest developments in green or biodegradable nanomaterials for increased sustainability Considers key challenges relating to market, health and environment, regulations and policy

Role of Microbes in Ecosystem Processes and Environmental Management explores microbial ecology and its impact on ecosystem processes while also highlighting the latest advancements in the application of microbes in environmental management and other industries. The book provides an overview of microbes in their natural environments, covering their role in soil health, carbon cycling, waste degradation, and plant-microbe interactions. It discusses the influence of microbes on weathering, erosion, and climate change, as well as their crucial role in ecosystem regulation and the restoration of degraded ecosystems. Sections also focus on the utilization of microbes in environmental management strategies as biocontrol agents and biological indicators of pollution and water quality and explore the practical applications of microbes in environmental bioremediation and for advanced microbial technologies in agriculture practices, food industries, energy production, mining, and healthcare. This is a comprehensive resource for researchers, faculty, postgraduate students, and industry professionals with a keen interest in microbial ecology and microbial-based product development.Details how microbes contribute to important processes in their natural environment, offering a comprehensive understanding of their role in maintaining ecosystem balanceHighlights the potential of utilizing microbes as a solution to managing real-world environmental challengesDiscusses the practical applications of microbial technology in areas such as water treatment, energy production, agriculture, and healthcare

This book helps the readers get a holistic understanding of the emergence of biochar-nanocomposite research. The low and long-term exposure of persistent hazardous pollutants in environment is well known for damaging the water, soil, sediments, and living biota. Thus, it is a crucial step to eliminate these pollutants from environment regimes to prevent the on-site destruction or the transfer into the food chain. Biochar is a carbon-rich solid material generated through pyrolysis of biomass, and currently, it is covering the hotspot in environmental management of pollutants.  It is being utilized for the efficient immobilization and sorption of organic pollutants, heavy metals, dyes, improvement of soil redox conditions, aggregate stabilization, photocatalytic degradation, and for carbon sequestration. The fascinating properties like surface area, porous structures, functional groups, and mineral components turn it into suitable candidate for the removal of various class of pollutants from environmental matrices. Different reactions like sorption, reduction, precipitation, solidification, and degradation are mainly responsible for the effective cleaning of xenobiotics from environment through biochar application. However, rapidly evolving contaminants in the environment have made the remediation more complex, expensive, and challenging. In view of these aspects, the modification of biochar through the doping of nanometals/metal oxides/surfactants/ or chemical entities will result in modified biochar with high surface area, more functional entities, improved physical, chemical, thermal, and mechanical characteristics with more adsorptive sites. Inclusion of these exclusive properties can be done through magnetic modification, impregnation of nanometals/ metal oxides/surfactants, amination, acid/base reactions, steam activation, etc. The resulted biochar-based nanocomposites have demonstrated a vital role in remediation of persistent organic pollutants, radionuclei, and heavy metals through the various interaction mechanisms like surface complexation, π–π interaction, electrostatic interaction, hydrogen bonding, Fenton process, and photocatalytic degradation. Currently, advanced research work has been carried out for the designing of modified composites of biochar to achieve maximum removal efficiency, reusability, biotoxicity, and sustainability. Hence, for selective removal of pollutants through designed biochar surface with the focused experimentation toward optimization of feedstocks, process variables, appropriate impregnation of nanomaterials, interaction with secondary pollutants, physical environment, longevity, and regeneration will definitely pave the way for safe and commercial application of biochar-based nanocomposites.