This book mainly focuses on the role of biofertilizers in managing soils for improving higher crops and vegetables as a substitute to chemical fertilizers. Highlights the valuable information for the mechanism of action, factors affecting and limitations of biofertilizers in the wider ecosystem. Presents diversity of techniques used across plant science. Design to cater to the needs of researchers, technologists, policy makers and undergraduates and postgraduates’ students studying, in the field of organic agriculture, soil microbiology, soil biology, soil fertility and fertilizers. Addresses plant responses to biofertilizers.

The third volume of Sustainable Soil and Land Management and Climate Change presents a complete overview of plant soil interactions in a climate affected by greenhouse gas emissions and organic carbon. It presents approaches and managements strategies for the stabilization of soil organic matter. The latest in the respected Footprints of Climate Variability on Plant Diversity series, this book enhances the reader's knowledge of the preservation of organic matter through microbial approaches as well as through soil and plant interactions. Written by teams of specialist scientists, it presents research outcomes, practical applications and future challenges for this important field. Features: Presents microbial tactics for the alleviation of potentially toxic elements in agricultural soils and for reclaiming saline soil. Provides an overview of scientific investigations into greenhouse gas emissions. Outlines priming techniques developed in response to a changing climate. This book is written for students of agronomy, soil science and the environmental sciences as well as researchers interested in management technologies to improve soil fertility.

Agriculture is one of the biggest contributors to climate change. More sustainable crop production based on agroecological principles is seen as a key solution to this challenge. Understanding and improving soil health is the foundation for this approach. Improving soil health provides a considered assessment of key management strategies to enhance the physical, chemical and biological health of soils in achieving sustainable improvements in crop yields. The book reviews the role of cultivation practices as well as organic and other soil amendments, such as biofertilizers. By assessing the dimensions of soil health, and reviewing the wealth of evidence on how well individual techniques contribute to improving soil, the book shows how farmers can achieve sustainable improvements in both productivity and profitability. Improving soil health will be a standard reference for researchers in soil and crop science, government and other agencies responsible for the health of agricultural soils, companies providing soil monitoring and management services and farmers wishing to further their knowledge on the latest developments in effective soil management.

Features: Brings together a multidimensional group of international scholars exploring the ethical dimensions of climate change and ecosystem. New strategies have pointed in this book for the better sustainable development. Design to cater a good overview of major challenges facing policy makers, researchers and ultimately humankind in dealing with climate change. This book summarizes the diverse features of vulnerability, adaptation, and amelioration of climate change in respect to plants, crops, soil, and microbes for the sustainability of the agricultural sector and, ultimately, food security for the future. Provide a state-of-the-art description of the physiological, biochemical, and molecular status of the understanding of abiotic stress in plants.

Features: Provide a state of the art description of the physiological, biochemical and molecular status of the understanding of abiotic stress in plants. Courses taught in universities from basics to advanced level in field of plant physiology, molecular genetics and bioinformatics this book will be used. Focuses on climatic extremes and their management for plant protection and production which is great threat to future generation and food security. Understanding of new techniques pointed out in this book will open the possibility of genetic engineering in crop plants with the concomitant improved stress tolerance. Addressing factors that are threatening future food production and providing potential solutions of these factors. Written by a diverse faction of internationally famed scholars, this book adds new horizons in the field of abiotic stress tolerance.

Global food security is increasingly challenging in light of population increase, the impact of climate change on crop production, and limited land available for agricultural expansion. Plant breeding and other agricultural technologies have contributed considerably for food and nutritional security over the last few decades. Genetic engineering approaches are powerful tools that we have at our disposal to overcome substantial obstacles in the way of efficiency and productivity of current agricultural practices. Genome engineering via CRISPR/Cas9, Cpf1, base editing and prime editing, and OMICs through genomics, transcriptomics, proteomics, phenomics, an metabolomics have helped to discover underlying mechanisms controlling traits of economic importance. Principle and Practices of OMICs and Genome Editing for Crop Improvement provides recent research from eminent scholars from around the world, from various geographical regions, with established expertise on genome editing and OMICs technologies. This book offers a wide range of information on OMICs techniques and their applications to develop biotic, abiotic and climate resilient crops, metabolomics and next generation sequencing for sustainable crop production, integration bioinformatics, and multi-omics for precision plant breeding. Other topics include application of genome editing technologies for food and nutritional security, speed breeding, hybrid seed production, resource use efficiency, epigenetic modifications, transgene free breeding, database and bioinformatics for genome editing, and regulations adopted by various countries around globe for genome edited crops. Both OMICs and genome editing are vigorously utilized by researchers for crop improvement programs; however, there is limited literature available in a single source. This book provides a valuable resource not only for students at undergraduate and postgraduate level but also for researchers, stakeholders, policy makers, and practitioners interested in the potential of genome editing and OMICs for crop improvement programs.

Features Provide a state-of-the-art description of the physiological, biochemical, and molecular status of the understanding of abiotic stress in plants. Addressing factors that are threatening future food production and providing potential solutions of these factors. Design to cater to the needs of those students engaged in the field of environmental sciences, soil sciences, agricultural microbiology, plant pathology, and agronomy. New strategies have pointed in this book for the better crop productivity and yield. Understanding of new techniques pointed out in this book will open the possibility of genetic engineering in crop plants with the concomitant improved stress tolerance.

Addresses the limits of the anthropogenic global warming theory advocated by the Intergovernmental Panel on Climate Change. Presents the main characters (drought tolerance, heat tolerance, water use efficiency, disease resistance, nitrogen use efficiency, nitrogen fixation, and carbon sequestration) necessary for climate resilient agriculture. Delivers both theoretical and practical aspects, and serves as base line information for future research. Provides valuable resource for those students engaged in the field of environmental sciences, soil sciences, agricultural microbiology, plant pathology, and agronomy. Highlights factors that are threatening future food production.

Global food security is increasingly challenging in light of population increase, the impact of climate change on crop production, and limited land available for agricultural expansion. Plant breeding and other agricultural technologies have contributed considerably for food and nutritional security over the last few decades. Genetic engineering approaches are powerful tools that we have at our disposal to overcome substantial obstacles in the way of efficiency and productivity of current agricultural practices. Genome engineering via CRISPR/Cas9, Cpf1, base editing and prime editing, and OMICs through genomics, transcriptomics, proteomics, phenomics, an metabolomics have  helped to discover underlying mechanisms controlling traits of economic importance.      Principle and Practices of OMICs and Genome Editing for Crop Improvement provides recent research from eminent scholars from around the world, from various geographical regions, with established expertise on genome editing and OMICs technologies. This book offers a wide range of information on OMICs techniques and their applications to develop biotic, abiotic and climate resilient crops, metabolomics and next generation sequencing for sustainable crop production, integration bioinformatics, and multi-omics for precision plant breeding. Other topics include application of genome editing technologies for food and nutritional security, speed breeding, hybrid seed production, resource use efficiency, epigenetic modifications, transgene free breeding, database and bioinformatics for genome editing, and regulations adopted by various countries around globe for genome edited crops. Both OMICs and genome editing are vigorously utilized by researchers for crop improvement programs; however, there is limited literature available in a single source. This book provides a valuable resource not only for students at undergraduate and postgraduate level but also for researchers, stakeholders, policy makers, and practitioners interested in the potential of genome editing and OMICs for crop improvement programs.

Climatic conditions are key determinants of plant growth, whether at the scale of temperature regulation of the cell cycle or at the scale of the geographic limits for a particular species. The climate is changing due to human activities - particularly the emission of greenhouse gases - therefore the conditions for the establishment, growth, reproduction, survival, and distribution of plant species are changing. In contrast to animals, plants are able to cease and resume growth. This flexibility in their architecture and growth pattern is partly achieved by the action of plant hormones. Still, the role of plant growth regulators (PGRs) in agriculture is modest compared to other agrochemicals, such as fungicides, herbicides, and insecticides. Plant Growth Regulators for Climate-Smart Agriculture is an invaluable guide to the varied roles filled by PGRs in the attainment of higher-quality, better-yielding crops. Salient Features (minimum 5): Explores plant growth regulators and anthropogenic climate change. Provides new insights related to hormonal cross-talk in plant development and stress responses. Sheds new light on the role of PGRs in agriculture in the attainment of higher-quality, better-yielding crops. Delivers valuable information on physiological and molecular mechanisms linked to the role of plant growth regulators in stress tolerance. Provides valuable knowledge for students of agronomy, plant physiology, molecular biology, and environmental sciences.

Climate Change and Plants: Biodiversity, Growth and Interactions Evidence is raised daily of the varying climate and its impression on both plants and animals. Climatic changes influence all agriculture factors, which can potentially adversely affect their productivity. Plant activities are intimately associated with climate and concentration of atmospheric carbon dioxide. Climate Change and Plants: Biodiversity, Growth and Interactions examines how plant growth characters influence and is influenced by climate change both in past and present scenarios. This book covers cutting-edge research of key determinants of plant growth in response to atmospheric CO2 enhancement and global warming. Features Discourses numerous areas of sustainable development goals projected by the UN as part of the 2030 agenda Highlights appropriate approaches for maintaining better plant growth under changing climatic conditions Presents diversity of techniques used across plant science Is designed to cater to the needs of researchers, technologists, policymakers and undergraduate and postgraduate students studying sustainable crop production and protection Addresses plant responses to atmospheric CO2 increases