Carbon Nanotubes in Agriculture: Specifications and Applications presents a comprehensive overview of the beneficial roles of carbon nano-tubes (CNT) in regulation of seed germination, plant metabolism and their applications in plant stress management with particular focus on agricultural crop plants. In light of current climate change trends, CNT-assisted crop yield is likely to play a significant role of improving plant health, enhancing root growth, and the improved tolerance to plants to a number of abiotic and biotic stresses. Primarily targeted towards the scientists and researchers in nanotechnology, nano-agriculture, nanomaterial-assisted crop improvement, as well as plant stress tolerance, plant biotechnology and crop yield, this book is the first to focus on the potential for carbon nanotubes in an agricultural setting.

This book, Crop Sustainability and Intellectual Property Rights, merges the concepts of traditional agriculture, crop sustainability, and intellectual property rights associated with plant protection and agricultural products. This volume provides a comprehensive account of the perspectives of traditional agriculture, crop sustainability, and various strategies associated with crop tolerance to adverse environmental conditions. It also highlights the role of agricultural intellectual property rights, along with the implications for plant patents, protection of farmers’ rights, and geographical indication in plant products to provide a broader outlook toward strategies for sustainable agriculture and global food security associated with IPR. The chapters provide an overview of sustainable crop cultivation in a variety of ways, with both traditional agriculture as well as with new biotechnological approaches. The volume explores several stress resilience strategies and issues for crops, considering how to mitigate the effect of increased carbon dioxide concentration, heavy metal pollution, over-salinized soils, and cold spells. It also discusses how to make desert farming more efficient; how to increase abiotic stress tolerance of crops with grafting, seed soaking/priming, soil amendment, and foliar applications; and more. The chapters on agricultural intellectual property rights address IPR in conjunction with food security, the rights of farmers, legal applications and protection of plant patents, protection of traditional knowledge, international legal issues, and plant variety protection rights in agriculture and more. The book will be valuable for academicians and researchers at universities and research institutes working on stress physiology, genomics, proteomics, genetic engineering, breeding, and sustainable agriculture. Furthermore, lawyers, policymakers, and legal executives associated with agriculture and plant science will find useful information as well.

1. Provides comprehensive analysis of the eco-physiological aspects of the novel plant growth regulators 2. Useful for investigators in plant physiology, developmental biology, crop biotechnology, plant breeding, plant signaling and communication. 3. Explains the integrative role of strigolactones, karrikins and alkamides in plant development and signaling

This book provides a comprehensive update on the recent developments concerning the role of plant neurotransmitters in signaling and communication. Physiological investigations over the past few decades have demonstrated that plants employ neurotransmitters in various signaling pathways. Plant-based neurotransmitters (serotonin, melatonin, dopamine, acetylcholine, and GABA) share biochemical similarities with those in animal systems in terms of their chemical nature and biochemical pathways. Plant-environment interaction associated with abiotic stress management, growth modulation, flowering, circadian rhythm, fruit ripening, and allelopathic interactions are a major focus of research in the field, and recent advances in genomic, trascriptomic, and metabolomic approaches have resulted in the deciphering of the molecular mechanisms associated with various neurotransmitters in plants. Other current and potential areas of investigation include the putative phytohormone phytomelatonin, and receptor-mediated signaling in plant neurotransmitters. Providing an up-to-date overview of molecular crosstalk mechanisms between various neurotransmitters, the book offers essential insights to help readers gain a better understanding of the physiology of plant signaling and communication with the environment.

This book discusses the recent advancements in the role of various biomolecules in regulating root growth and development. Rhizobiology is a dynamic sub discipline of plant science which collates investigations from various aspects like physiology, biochemistry, genetic analysis and plant-microbe interactions. The physiology and molecular mechanisms of root development have undergone significant advancements in the last couple of decades. Apart from the already known conventional phytohormones (IAA, GA, cytokinin, ethylene and ABA), certain novel biomolecules have been considered as potential growth regulators or hormones regulating plant growth and development. Root phenotyping and plasticity analysis with respect to the specific functional mutants of each biomolecule shall provide substantial information on the molecular pathways of root signaling. Special emphasis provides insights on the tolerance and modulatory mechanisms of root physiology in response to light burst, ROS generation, agravitrophic response, abiotic stress and biotic interactions. Root Apex Cognition: From Neuronal Molecules to Root-Fungal Networks and Suberin in Monocotyledonous Crop Plants: Structure and Function in Response to Abiotic Stresses" are available open access under a Creative Commons Attribution 4.0 International License via link.springer.com. Chapters "Root Apex Cognition: From Neuronal Molecules to Root-Fungal Networks and Suberin in Monocotyledonous Crop Plants: Structure and Function in Response to Abiotic Stresses" are available open access under a Creative Commons Attribution 4.0 International License via link.springer.com.