Javid A. Parray

Patterns, Function and Application of Seed Microbiome: Bacteria, Fungi and Viruses presents the current understanding of seed and microbiota associations, emphasizing recent findings that highlight the latest insights into these interactions, and how they may ultimately influence plant ecology, health and productivity in both natural and agricultural systems. The development and dispersal of seeds and their transition to seedlings are among the most critical stages of the life cycle of plants and seed health is of crucial global importance for producing both quantity and high quality crops to feed world’s population. It is important for seeds to be produced that contain the best hybrid embryo so that it is free of diseases, includes beneficial endophytes and ensures a healthy start of a seedling. Focusing on the role of seed microbiota, their transmission and implications for producing healthier seeds as well as the relationship between the seed microbiome and primed plant resistance this book reveals the targeted use of the seed microbiome to enrich the soil biodiversity and its resilience and its resulting impact on plant health and yield. also explores the importance of nanotechnology in the development and production of crops for both improved plant production, and plant protection. It explores the different microbes that are vectored onto and within the seeds of both cultivated and non-cultivated plants, with an emphasis on the importance and roles of seed microbiomes in sustainable agriculture. It explains how to change seeds to increase microbiome vectoring; repairing damaged ones, and conserves seed microbiota. It also present seed microbiome roles for plant health and design effective microbiome engineering.

The primary focus of the topic is on the production of energy. Here, energy production typically refers to the conversion of waste algal biomass into various forms of usable energy. This could include electricity, biofuels (e.g., biodiesel, bioethanol), biogas, or other forms of renewable energy. Conversion of algal biomass to fuels via extraction of lipids (and potentially other components), through 'algal lipid upgrading' or ALU pathway, combined algal process (CAP) and parallel algal process (PAP). ALU approach based on a biochemical processing strategy to selectively recover and convert select algal biomass components to fuels, namely carbohydrates to ethanol and lipids to a renewable diesel blendstock (RDB) product. The scope of the topic encompasses the various methods and technologies used to convert waste algal biomass into energy. This could involve processes like anaerobic digestion, fermentation, pyrolysis, hydrothermal liquefaction, or other innovative techniques. The topic may touch upon ongoing research, technological advancements, and potential areas of improvement related to waste algal biomass-based energy production.

Provides detailed information about the use of nanotechnology in remediating waste and pollution in agriculture Nano-Technological Intervention in Agricultural Productivity explores sustainable, eco-friendly technologies for remediating wastes and contaminated areas in both water and land ecosystems. Focusing on nano-technological innovations that use microbes and microbial agents to improve the quality and pollutant discharge of contaminated sites, this comprehensive volume also discusses molecular approaches for the characterization of nanoparticles, the biosynthetic pathways of microbes, gene and protein expression studies for bio-deterioration techniques, and more. Organized into nine chapters, the book opens with a thorough overview of the functions, classification, properties, synthesis, and applications of nanoparticles. Following a discussion of the environmental and agricultural implications of nanotechnology, the authors examine the current role and future prospects of nanotechnology in managing plant diseases, improving agri-food production, and increasing agricultural productivity. Subsequent chapters cover lignin nanoparticles, various applications of nanotechnology in agriculture, and nano-based advances in plant and microbial science. Offering an up-to-date account of the role of nanotechnologies in agricultural bioremediation, this book: Explores biotechnological advances in the development of sophisticated green technologies for waste minimization and waste control Emphasizes the use of microbes for degradation and removal of various xenobiotic substances Discusses bioremediation approaches in relation to the impact of increased urbanization and industrialization on the environment Covers a variety of applications of nanotechnology in agriculture, including nano-fertilizers, nano-biosensors, nano-pesticides, and nanoparticle protection in plants Nano-Technological Intervention in Agricultural Productivity is a valuable resource for students in plant biotechnology and agricultural science and engineering, as well as an important reference for researchers in plant biotechnology and agricultural sciences, particularly those with interest in the use of nanomaterials for pollution remediation and sustainable development.