05493nam 2200793 a 450 991096103470332120250513230525.097866132347599781283234757128323475097898143242509814324256(CKB)3400000000016325(EBL)840575(OCoLC)748215457(SSID)ssj0000539769(PQKBManifestationID)12216430(PQKBTitleCode)TC0000539769(PQKBWorkID)10580172(PQKB)10980024(MiAaPQ)EBC840575(WSP)00007916(Au-PeEL)EBL840575(CaPaEBR)ebr10493512(CaONFJC)MIL323475(Perlego)850187(EXLCZ)99340000000001632520101230d2011 uy 0engur|n|---|||||txtccrOrbiting the moons of Pluto complex solutions to the Einstein, Maxwell, Schrödinger and Dirac equations /Elizabeth A. Rauscher, Richard L. Amoroso1st ed.Hackensack, N.J. World Scientificc20111 online resource (412 p.)K & E series on knots and everything ;v. 45Description based upon print version of record.9789814324243 9814324248 Includes bibliographical references and index.Preface; Contents; 1. Introduction - Orbiting the Moons of Pluto; 1.1 Introduction; 1.2 Multidimensional Minkowski Space; References; 2. Structure, Properties and Implications of Complex Minkowski Spaces; 2.1 Some Predictions of Complex Geometries; 2.2 Multidimensional Geometric Models and Macroscopic Remote Connectedness; 2.3 The Lorentz Condition in Complex 8-Space Geometry and Tachyonic Signaling; 2.4 Velocity of Propagation in Complex 8-Space; 2.5 Kaluza-Klein Geometries: A Possible Unification of Electro- magnetic and Gravitational Phenomena2.6 Additional Thoughts on Current Physical TheoryReferences; 3. Major Principles of Physics: Poincaré Invariance, Analyticity, Unitarity and Complex Minkowski Space; 3.1 Major Principles of Physics; References; 4. Nonlocal Interconnectedness as a Fundamental Principle of Reality; 4.1 Bell's Theorem and Its Experimental Verification; 4.2 More Recent Long Distance Confirmations of Bell's Nonlocality; 4.3 Implications of Bell's Nonlocality Theorem; 4.4 Conceptual and Philosophical Implications of Bell's Theorem; 4.4.1 Bell's Theorem; 4.4.2 Principle of Local Causes4.4.3 Some Possible Conclusions About Bell's Theorem4.4.4 Contra-Factual Definiteness Fails; 4.4.5 Possible Interpretations of the Wave Function, Y; 4.4.6 Objections to the Reality of Quantum Theory; 4.4.7 Locality Fails; 4.4.8 Concluding Remarks; 4.5 Other Nonlocal Interactive Phenomenon and the Particle-Wave "Paradox" Resolved; 4.5.1 Young's Double Slit Experiment and Its Extension, the Wheeler Delayed Choice Experiment; 4.5.2 Delayed Choice as an Extension of Young's Double Slit Experiment; 4.5.3 The Aharanov-Bohm Experiment, Fields and Potentials as Mechanisms of Non-Local Interactions4.5.4 Some Topics for Interference Experiments4.5.5 Ernst Mach, Frames of Reference and Nonlocality; 4.6 Conclusion; References and Notes; 5. The Complexification of Maxwell's Equations; 5.1 Complex Electromagnetic Fields; 5.2 Complex Electromagnetic Variables in Complex Multidimensional Spaces; 5.3 Complex Electromagnetic Field Vectors, Virtual Energy States and Magnetic Monopole Interpretations; 5.4 Higgs Field Magnetic Monopole; 5.5 Some Further Speculations on Monopole Structures; 5.6 The Structure of Non-Hertzian Waves in Complex Geometries and Electromagnetic Energy Transmission5.7 Summary and Concluding RemarksReferences and Notes; 6. Vector and Scalar Potentials, Advanced and Retarded Waves and Nonlocal Phenomena; 6.1 Vector and Scalar Potentials and Fields; 6.2 Advanced and Retarded Solutions; References; 7. The Complex Form of Relativistic Maxwell's Equations; 7.1 Relativistic Conditions for Maxwell's Equations in Complex Geometries and Invariance of the Line Element; 7.2 Complex E and B in Real 4-Space and the Complex Lorentz Condition; 7.3 Complex Electromagnetic Forces in a Gravitational Field; References8. Real and Complex Amended Maxwell's Equations for Non-Abelian Gauge GroupsThe Maxwell, Einstein, Schrödinger and Dirac equations are considered the most important equations in all of physics. This volume aims to provide new eight- and twelve-dimensional complex solutions to these equations for the first time in order to revealK & E series on knots and everything ;v. 45.Generalized spacesGravitational fieldsElectromagnetic theoryQuantum field theoryPluto (Dwarf planet)SatellitesGeneralized spaces.Gravitational fields.Electromagnetic theory.Quantum field theory.530.1Rauscher Elizabeth A1818731Amoroso Richard L1113395MiAaPQMiAaPQMiAaPQBOOK9910961034703321Orbiting the moons of Pluto4378125UNINA10798nam 22004573 450 991104092820332120251115060326.01-394-19257-61-394-19259-2(CKB)42027438900041(MiAaPQ)EBC32409819(Au-PeEL)EBL32409819(EXLCZ)994202743890004120251115d2025 uy 0engur|||||||||||txtrdacontentcrdamediacrrdacarrierCustom-Designed Crop Breeding, 2 Volume Set1st ed.Newark :John Wiley & Sons, Incorporated,2025.©2026.1 online resource (879 pages)1-394-19256-8 Cover -- Volume 1 -- Half Title Page -- Title Page -- Copyright -- Contents - Volume-1 -- Contributors -- Editors -- Preface -- Acknowledgment -- Part I: Genomics-based Precision Breeding -- 1: Innovative Approaches in Crop Design -- 1.1 Introduction -- 1.2 A Brief Look into the History of Plant Breeding Technologies -- 1.3 New Plant Improvement Tools -- 1.4 Plant-Microbe Interactions toward Crop Improvement -- 1.5 Speed Breeding -- 1.6 Future Prospects -- 1.7 Conclusion and Prospects -- References -- 2: Enhancing Drought Tolerance and Crop Adaptability: Genomic Advances for a Sustainable Agriculture -- 2.1 Introduction -- 2.2 Genomic Innovation for Crop Drought Management -- 2.3 The Key Role of Advancing Genomics Tools -- 2.4 Genetic Improvement Technology -- 2.5 Novel Genomic Breeding Techniques -- 2.6 Breeding Based on Systems Biology -- 2.7 Rapid Breeding and Genomic Selection -- 2.8 CRISPR/Cas9 and CRISPR/Cas12a -- 2.9 DNA and RNA A Base Edit -- 2.10 DNA Prime Editing -- 2.11 Epigenome Editing -- 2.12 Conclusion and Prospects -- References -- 3: Progress of Functional Genomics in Crop Plants -- 3.1 Introduction -- 3.2 Branches of Genomics -- 3.3 Databases and Applications -- 3.4 History of Genomics -- 3.5 The Comprehensive Progress and Ranking of Functional Genomics and Systems Biology -- 3.6 Application of Functional Genomics -- 3.7 Current Status of Genomics and Functional Genomics -- 3.8 Advances in Plant Functional Genomics -- 3.9 Functional Genomics for Precision Crop Breeding -- 3.10 Conclusion and Future Prospectus -- References -- 4: Breeding by Design: Interaction of Linkage Maps and Molecular Markers in Major Oilseed Crops under Abiotic Stress -- 4.1 Introduction -- 4.2 Conclusion and Prospects -- References -- 5 Stability Statistics in Multi-environment Trials -- 5.1 Introduction -- 5.2 Genotype and Environment Interaction.5.3 Multi-environment Trials (METs -- 5.4 Stability Statistics -- 5.5 Conclusion and Prospects -- References -- Part II: Innovative Breeding Technologies -- 6: Crop Breeding for Climate Resilience: Integrating Genomics and Phenomics with Bioinformatics -- 6.1 Introduction -- 6.2 Genomic Approaches in Crop Breeding -- 6.3 High-throughput Phenotyping for Climate Adaptation -- 6.4 Bioinformatics Tools and Resources for Crop Breeding -- 6.5 Integrating Genomics and Phenomics in Crop Breeding -- 6.6 Future Prospects and Challenges -- 6.7 Conclusion and Prospects -- References -- 7: High-throughput Phenotyping of Traits Associated with Climate Resilience in Crop Plants -- 7.1 Introduction -- 7.2 The Phenomics Bottleneck -- 7.3 Plant Response Toward the Stress -- 7.4 HTP Techniques -- 7.5 Extraction of Phenotypic Data and its Analysis -- 7.6 Conclusion and Prospects -- References -- 8: Enroute to Climate-resilient Crops: QTL Mapping and Beyond -- 8.1 Introduction -- 8.2 QTL Mapping: Concept and Methods -- 8.3 Mapping-to-MAS Strategy -- 8.4 QTL Mapping versus GWAS: The Road Not Taken -- 8.5 QTL Mapping-to-MAS versus GS: When to Select Which Approach -- 8.6 QTL to Candidate Gene -- 8.7 Implementation of Mapping-to-MAS Strategy for Cultivar Development -- 8.8 Nature of Traits Associated with Climate Resiliency -- 8.9 Conclusion and Perspectives -- References -- 9: Crop Biofortification for Food Security under the Era of Climate Change -- 9.1 Introduction -- 9.2 Hidden Hunger and World Famine -- 9.3 Agricultural Production Challenges -- 9.4 Climate Change Effect on Crop Production -- 9.5 Synthetic Fertilizers and Their Role in Climate Change -- 9.6 Biofortification for Human Health -- 9.7 Biofortification Approaches (Conventional Breeding and Agronomic Tactics) -- 9.8 Genomic Approaches -- 9.9 Transgenic Approach -- 9.10 Genome Editing.9.11 Nanoencapsulation Strategies for Advancing Biofortification -- 9.12 Microbial Biofortification -- 9.13 Successful Stories of Biofortified Crops, Challenges and Limitations -- 9.14 Conclusion -- References -- Part III: Artificial Intelligence and Machine Learning -- 10: Automated High-throughput Plant Phenotyping Systems -- 10.1 Introduction -- 10.2 Components of Automated High-throughput Plant Phenotyping Systems -- 10.3 Types of Automated High-throughput Plant Phenotyping Systems -- 10.4 Applications of Automated High-throughput Plant Phenotyping Systems -- 10.5 Positron Emission Tomography -- 10.6 Conclusion and Prospects -- References -- 11: Next-generation Artificial Intelligence in Plant Breeding -- 11.1 Introduction -- 11.2 The Evolution of Molecular Breeding Techniques -- 11.3 AI-powered Breeding: Revolutionizing Crops for a Sustainable Future -- 11.4 Beyond Traditional Breeding: Releasing the Power of AI for Next-generation Crops -- 11.5 Challenges -- 11.6 Conclusion and Prospects -- References -- 12: Prediction of Traits Using Artificial Intelligence Machine Learning -- 12.1 Introduction -- 12.2 Forms of Artificial Intelligence and Their Uses in Agriculture -- 12.3 Forms of ML and Their Uses in Agriculture -- 12.4 Challenges of Using ML in Agriculture -- 12.5 Future of AI and ML -- 12.6 Conclusion and Prospects -- References -- 13: Smart Plant Breeding -- 13.1 Introduction -- 13.2 Milestones and Importance of Plant Breeding -- 13.3 Drones of Plant Breeding -- 13.4 Smart Germplasm Resources -- 13.5 Smart Approaches of GEI -- 13.6 Bioinformatics -- 13.7 Plant Breeding Objectives with Smart Breeding Technologies -- 13.8 Smart Plant Breeding Methods -- 13.9 Conclusion -- References -- 14: Autonomous Field Phenotyping: Revolutionizing Crop Breeding with Artificial Intelligence -- 14.1 Introduction -- 14.2 Historical Perspective and Evolution.14.3 Phenotyping Robots -- 14.4 Significance of Autonomous Field Phenotyping in Modern Breeding -- 14.5 Technologies Driving Autonomous Phenotyping -- 14.6 Sensor Technologies for Field Data Collection -- 14.7 Advancements in Remote Sensing -- 14.8 Data Collection and Processing Methods -- 14.9 Applications in Crop Improvement -- 14.10 Accelerating Crop Development Cycles -- 14.11 AI Integration with Traditional Breeding Practices -- 14.12 Emerging Trends and Future Prospects -- 14.13 Conclusion and Prospects -- References -- 15: Integration of Machine Learning in Plant Breeding -- 15.1 Introduction -- 15.2 Plant Genomics and Phenomics -- 15.3 Phenotypic Selection -- 15.4 Genetic and Phenotypic Modeling: An Integrated Approach -- 15.5 Challenges in the Integration of ML and Phenotyping for Crop Improvement -- 15.6 ML in Plant Breeding -- 15.7 Conclusion and Prospects -- References -- Index -- Volume 2 -- Half Title Page -- Title Page -- Copyright -- Contents - Volume 2 -- Contributors -- Editors -- Preface -- Acknowledgment -- Part IV: Abiotic Stress Tolerance -- 16: Genetics and Genomics of Root Architecture Traits in Response to Environmental Stress in Plants -- 16.1 Introduction -- 16.2 Root Architecture -- 16.3 Impact of Environmental Stresses on RA -- 16.4 Plants' Molecular Response to Environmental Stress in RA -- 16.5 Conclusion and Prospects -- References -- 17: Physiological Tools for Drought-tolerant Crops Design -- 17.1 Introduction -- 17.2 Natural Crop Diversity as a Source for Drought-tolerance Genes -- 17.3 Some Physiological Tools to Improve Crop Tolerance to Drought Stress -- 17.4 Key Role of Physiology in DT Improvement -- 17.5 Conclusion and Future Prospects -- References -- 18: Customizing Crops for Salinity Tolerance: Toward Resilient Crop Production Systems -- 18.1 Introduction.18.2 Plant Adaptation Responses to Salt Stress: Stress Management at Physiological and Molecular Levels -- 18.3 Introgressing Salt Tolerance in Crop Plants -- 18.4 Biotechnological Interventions: Genetic Manipulation for Salt Tolerance -- 18.5 Identifying Novel Genes Conferring Salt Tolerance -- 18.6 Conclusion and Prospects -- References -- 19: Haplotype-based Breeding for Stress Tolerance in Plants -- 19.1 Introduction -- 19.2 Haplotypes and Their Significance in Plant Breeding -- 19.3 The Journey from Traits to Haplotypes: A Comprehensive Roadmap for Stress Breeding -- 19.4 Challenges and Limitations -- 19.5 Conclusion and Prospects -- References -- 20: Designer Crops: Optimal Root System Architecture for Nutrient Acquisition -- 20.1 Introduction -- 20.2 Nitrogen -- 20.3 Phosphorus -- 20.4 Potassium -- 20.5 Conclusion and Prospects -- References -- 21: Genetic Gains in Crop Yield Through Genomic Selection Under Drought Stress -- 21.1 Introduction -- 21.2 Drought Stress and Plant Responses -- 21.3 Strategies to Overcome Drought Stress -- 21.4 The Fundamentals of Genetic Gain -- 21.5 GS and Its Role in Crop Improvement -- 21.6 Future Perspectives, Challenges, and Conclusion -- References -- Part V: Biotic Stress Tolerance -- 22: Designer Crops for Biotic Stress Tolerance: Technologies and Applications -- 22.1 Introduction -- 22.2 Influence of Biotic Stress on Crop Plants -- 22.3 Crop Designing Strategies -- 22.4 Developing Technologies for Biotic Stress Management -- 22.5 Application and Commercialization -- 22.6 Conclusion and Prospects -- References -- 23: Designer Crops Developed Against Insect Pests -- 23.1 Introduction -- 23.2 Importance of Insect Resistance in Crops -- 23.3 Natural Mechanisms of Insect Resistance in Crops -- 23.4 Genetically Modified Insect-resistant Crops -- 23.5 Advantages of Genetically Engineered Insect-resistant Crops.23.6 Genetic Engineering Techniques for Developing Insect-resistant Crops.Discover strategies to develop crop plants with specific traits needed to meet the specific challenges.Climate change poses an existential threat to global food supplies, with even modest increases in global temperature potentially spelling disaster for crop productivity.631.52Jain Shri Mohan1589017MiAaPQMiAaPQMiAaPQBOOK9911040928203321Custom-Designed Crop Breeding, 2 Volume Set4456803UNINA