08100nam 2200493 450 99647206070331620231110222749.09783030967802(electronic bk.)9783030967796(MiAaPQ)EBC6953634(Au-PeEL)EBL6953634(CKB)21513286600041(PPN)262170914(EXLCZ)992151328660004120221118d2022 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierElectromagnetism with solved problems /Hiqmet KamberajCham, Switzerland :Springer,[2022]©20221 online resource (400 pages)Undergraduate Texts in Physics Print version: Kamberaj, Hiqmet Electromagnetism Cham : Springer International Publishing AG,c2022 9783030967796 Includes bibliographical references and index.Intro -- Preface -- Contents -- 1 Electrostatics in Free Space -- 1.1 Electrical Charges -- 1.2 Coulomb's Law -- 1.3 Coulomb's Law for a System of Charges -- 1.4 Electric Field -- 1.4.1 Force Fields -- 1.4.2 Superposition Principle -- 1.5 Electric Field Lines -- 1.6 Motion in Uniform Electric Field -- 1.7 Exercises -- Reference -- 2 Gauss's Law -- 2.1 Electric Flux -- 2.1.1 Uniform Electric Field -- 2.1.2 General Electric Field Flux -- 2.2 Gauss's Law -- 2.2.1 Gauss's Law for a System of Charges -- 2.3 Applications of Gauss's Law to Insulators -- 2.4 Conductors in Electrostatic Equilibrium -- 2.4.1 Property 1 -- 2.4.2 Property 2 -- 2.4.3 Property 3 -- 2.4.4 Property 4 -- 2.5 Exercises -- Reference -- 3 Electrostatic Potential -- 3.1 Electrostatic Potential Energy -- 3.2 Electric Potential -- 3.3 Potential Difference in a Uniform Electric Field -- 3.4 Equipotential Surface -- 3.5 Electric Potential of a Point Charge -- 3.6 Electric Potential of a System of Point Charges -- 3.7 Electric Potential of a Continuous Charge Distribution -- 3.8 Differential form of Electric Potential -- 3.9 Multipole Expansion -- 3.10 Electric Potential of a Charged Conductor -- 3.10.1 Cavity Within a Conductor -- 3.11 Exercises -- References -- 4 Capacitance and Dielectrics -- 4.1 Capacitance -- 4.2 Calculating Capacitance -- 4.2.1 Spherical Conductors -- 4.2.2 Parallel-Plate Capacitors -- 4.3 Combination of Capacitors -- 4.3.1 Parallel Combination -- 4.3.2 Series Combination -- 4.4 Energy Storage in the Electric Field -- 4.5 Electrostatics of Macroscopic Media and Dielectrics -- 4.5.1 Dielectrics -- 4.5.2 Comparison Between Dielectric Materials and Conductors -- 4.5.3 Molecular Theory of Dielectrics -- 4.5.4 Energy Stored in Capacitor -- 4.6 Electric Polarization -- 4.7 Set of Maxwell Equations for Electrostatic Field.4.7.1 Maxwell Equations for Free Space Electrostatic Field -- 4.7.2 Maxwell Equations for Dielectric Media Electrostatic Field -- 4.8 Potential Energy of Electrostatic Field -- 4.9 Exercises -- References -- 5 Electric Current -- 5.1 Electric Current -- 5.1.1 Direction of Electric Current -- 5.1.2 Charge Carrier -- 5.2 Microscopic Model of Current -- 5.3 Resistance and Ohm's Law -- 5.3.1 Ohm's Law -- 5.3.2 Classical Model for Electrical Conduction -- 5.3.3 Resistance and Temperature -- 5.4 Superconductors -- 5.5 Electric Energy and Power -- 5.6 Electromotive Force -- 5.7 Exercises -- Reference -- 6 Magnetic Field -- 6.1 Magnetic Field -- 6.2 Magnetic Force Acting on a Current-Carrying Conductor -- 6.3 Torque on a Current Loop in a Uniform Magnetic Field -- 6.4 Motion of a Charged Particle in a Uniform Magnetic Field -- 6.5 Exercises -- Reference -- 7 Sources of Magnetic Field -- 7.1 Biot-Savart Law -- 7.2 Magnetic Force Between Two Parallel Conductors -- 7.3 Ampére's Law -- 7.4 Magnetic Flux -- 7.5 Gauss's Law in Magnetism -- 7.6 Displacement Current -- 7.7 Exercises -- References -- 8 Magnetism in Matter -- 8.1 Magnetic Moments of Atoms -- 8.2 Magnetization Vector and Magnetic Field Strength -- 8.3 Classification of Magnetic Substances -- 8.3.1 Ferromagnetism -- 8.3.2 Paramagnetism -- 8.3.3 Diamagnetism -- 8.4 The Magnetic Field of the Earth -- 8.5 Faraday's Law of Induction -- 8.6 Rowland Ring Apparatus -- 8.7 Maxwell's Equations of Magnetism -- 8.8 Vector Potential -- 8.9 Multipole Expansion -- 8.10 Energy of the Magnetic Field -- 8.11 Exercises -- References -- 9 Maxwell's Equations of Electromagnetism -- 9.1 Maxwell's Equations of Electromagnetism -- 9.2 Vector and Scalar Potentials of Electromagnetic Field -- 9.3 Electromagnetic Field Energy and Conservation Law -- 9.4 Conservation Law of Momentum.9.5 Dynamics of Charged Particles in Electromagnetic Fields -- 9.6 Macroscopic Maxwell Equations -- 9.7 Exercises -- References -- 10 More About Faraday's Law of Induction -- 10.1 Moving Conductor in a Closed Circuit -- 10.1.1 Induced Electric Potential and Electric Field -- 10.1.2 Generators and Motors -- 10.2 Inductance -- 10.2.1 Self-inductance -- 10.2.2 Mutual Inductance -- 10.3 Oscillations in an LC Circuit -- 10.4 The RL Circuit -- 10.5 The RLC Circuit -- 10.5.1 Case 1 -- 10.5.2 Case 2 -- 10.5.3 Case 3 -- 10.6 Alternating Current Circuits -- 10.6.1 AC Sources and Phases -- 10.6.2 Resistors in an AC Circuit -- 10.6.3 Inductors in an AC Circuit -- 10.6.4 Capacitors in an AC Circuit -- 10.6.5 The RLC Series in an AC Circuit -- 10.7 Power in the AC Circuit -- 10.8 Resonance in the RLC Series Circuit -- 10.9 Exercises -- Reference -- 11 Some Applications of Electromagnetic Theory -- 11.1 Electrostatic Properties of Macromolecular Solutions -- 11.1.1 The pH and Equilibrium Constant -- 11.1.2 Charge on DNA and Proteins -- 11.1.3 Charge States of Amino Acids -- 11.1.4 Salt Binding -- 11.1.5 Energy Cost of Assembling a Collection of Charges -- 11.1.6 The Poisson-Boltzmann Equation -- 11.1.7 Calculation of pKa of Amino Acids in Macromolecules -- 11.2 Wireless Charging -- 11.2.1 Tightly Coupled Wireless Power Systems -- 11.2.2 Loosely Coupled Highly Resonant Systems -- 11.3 Exercises -- References -- 12 Electromagnetic Waves in Vacuum and Linear Medium -- 12.1 Electromagnetic Wave Equations in Vacuum -- 12.2 Relationships Between k, E, B -- 12.3 Electromagnetic Waves Equations in Linear Medium -- 12.4 Energy and Momentum of Electromagnetic Waves -- 12.5 Coherence of Electromagnetic Waves -- 12.6 Polarization of Electromagnetic Waves -- 12.6.1 Linear Polarization -- 12.6.2 Circular and Elliptical Polarization.12.7 Reflection and Refraction of Electromagnetic Waves -- 12.7.1 Laws of Reflection and Refraction -- 12.8 Fresnel Equations -- 12.8.1 Boundary Conditions -- 12.8.2 Perpendicular Polarization -- 12.8.3 Parallel Polarization -- 12.8.4 External and Internal Reflection -- 12.8.5 Normal Incidence of Electromagnetic Waves -- 12.8.6 Reflectance and Transmittance -- 12.9 Exercises -- References -- 13 Electromagnetic Waves in Dispersive Media -- 13.1 Dispersion and Absorption -- 13.1.1 Lorentz's Model of Oscillations in Dielectrics -- 13.2 Dispersion -- 13.2.1 Wave Packets and Group Velocity -- 13.2.2 Normal and Anomalous Dispersion -- 13.3 Refractive Index of a Conductor -- 13.4 Wave Propagation in a Dilute Plasma -- 13.4.1 Electromagnetic Waves in a Dilute Plasma -- 13.4.2 Phase and Group Velocity in a Dilute Plasma -- 13.4.3 Plasma and Dielectric at High Frequency -- 13.5 Exercises -- References -- Appendix Vectorial Analysis -- A.1 Vector Calculus -- A.2 Vector Differential Operators -- A.3 Stokes' Formula -- A.4 Gauss's Formula -- A.5 Some Useful Formula -- A.6 Laplacian -- A.7 Curvilinear Coordinates.Undergraduate Texts in Physics ElectromagnetismElectromagnetismMathematicsElectromagnetism.ElectromagnetismMathematics.537.6Kamberaj Hiqmet843402MiAaPQMiAaPQMiAaPQ996472060703316Electromagnetism2834274UNISA02435nam0 22004933i 450 VAN016789420230614031850.473N978331925074820210629d2016 |0itac50 baengCH|||| |||||Optical Properties of Metallic NanoparticlesBasic Principles and SimulationAndreas TrüglerChamSpringer2016xix, 217 p.ill.24 cm001VAN00239902001 Springer series in materials science210 BerlinSpringer232VAN0167898Optical Properties of Metallic Nanoparticles : Basic Principles and Simulation181153481-XXQuantum theory [MSC 2020]VANC019967MF78-XXOptics, electromagnetic theory [MSC 2020]VANC022356MF81V10Electromagnetic interaction; quantum electrodynamics [MSC 2020]VANC027733MF78A48Composite media; random media in optics and electromagnetic theory [MSC 2020]VANC035199MF78A15Electron optics [MSC 2020]VANC036196MF81V19Other fundamental interactions in quantum theory [MSC 2020]VANC036203MFBoundary Element MethodsKW:KElectrodynamics at the NanoscaleKW:KMNPBEM ToolboxKW:KNonlocal PlasmonicsKW:KParticle PlasmonsKW:KPlasmon ImagingKW:KPlasmonics and NanoopticsKW:KSimulation and Optical Properties of Metallic NanoparticlesKW:KSurface PlasmonsKW:KTheoretical Description of Metallic NanoparticlesKW:KCHChamVANL001889TrüglerAndreasVANV151707808453Springer <editore>VANV108073650ITSOL20240614RICAhttp://doi.org/10.1007/978-3-319-25074-8E-book – Accesso al full-text attraverso riconoscimento IP di Ateneo, proxy e/o ShibbolethBIBLIOTECA DEL DIPARTIMENTO DI MATEMATICA E FISICAIT-CE0120VAN08NVAN0167894BIBLIOTECA DEL DIPARTIMENTO DI MATEMATICA E FISICA08CONS e-book 2803 08eMF2803 20210629 Optical Properties of Metallic Nanoparticles : Basic Principles and Simulation1811534UNICAMPANIA05415nam 22006375 450 991103505730332120251031120436.03-032-04527-410.1007/978-3-032-04527-0(CKB)41986955000041(MiAaPQ)EBC32384039(Au-PeEL)EBL32384039(DE-He213)978-3-032-04527-0(OCoLC)1549519306(EXLCZ)994198695500004120251031d2025 u| 0engur|||||||||||txtrdacontentcrdamediacrrdacarrierAccelerated Plant Breeding, Volume 5 Forage Crops /edited by Shabir Hussain Wani, Satbir Singh Gosal1st ed. 2025.Cham :Springer Nature Switzerland :Imprint: Springer,2025.1 online resource (0 pages)Biomedical and Life Sciences Series3-032-04526-6 Forage Genetic Resources—An Indian Scenario -- Utilization of genetic resources through molecular and genomic approaches for forage barley improvement -- Genomics-assisted Breeding for fodder quality improvement in forage sorghum -- Accelerated Breeding in Bajra Using Genomic Approaches -- QTLomics approach for improvement of Finger Millet -- Current Status and Prospects of Genomics in Guar Breeding Program -- Guinea grass (Megathyrsus maximus): Crop Diversity and Genetic Improvement -- Genomic Approaches for Alfalfa breeding: Advances and future prospects -- Utilization of genetic and genomic resources for accelerated breeding for millet improvement -- Accelerated breeding approaches for improved productivity and quality in dual-purpose oats -- Breeding approaches for Maize improvement to enhance its forage potential -- Genome editing tools for improving yield of forage crops.Human population growth and potentially irreversible climate changes have raised worldwide concerns regarding food and nutritional security. Plant breeding that once considered “art and science for changing and improving the characteristics of plants” is now heavily dependent on biotechnologies. The endeavor is a continuous process which results in new varieties required by farmers to improve their crop yields and quality of the produce. On the other hand, in the current scenarios of challenging environmental impact, there is emergence of new insect-pests and new pathotypes of disease causing agents. Accordingly what used to be minor insect-pests/pathogens are rapidly becoming major biotic stress factors. Along with heat and drought, they pose serious threats to crop productivity in many parts of the world. Current WTO analysis reveals that farmers want new high yielding varieties suitable not only for local consumption but also for commercial export. Conventional breeding approaches at this juncture seem inadequate to meet the growing demand for superior varieties. Efficiency improvement of existing cultivars is one way to meet these challenges. Historically, plant improvement has been largely confined to improving yield, quality, resistance to diseases and insect-pests and tolerance to abiotic stresses. Now growers demand high yielding varieties that possess early maturity, higher harvest index, dual purpose forages, varieties with nutrient-use efficiency/water-use efficiency, wider adaptability, suitable for mechanized harvesting, better shelf life, better processing quality, with improved minerals, vitamins, amino acids, proteins, antioxidants and bioactive compounds. Conventional plant breeding methods aiming at the improvement of a self-pollinating crop, such as wheat, usually take 10-12 years to develop and release of the new variety. During the past 10 years, significant advances have been made and accelerated methods have been developed for precision breeding and early release of crop varieties. This multi-volume work summarizes concepts dealing with germplasm enhancement and development of improved varieties based on innovative methodologies that include recent omics approaches, marker assisted selection, marker assisted background selection, genome wide association studies, next generation sequencing, genetic mapping, genomic selection, high-throughput genotyping, high-throughput phenotyping, mutation breeding, reverse breeding, transgenic breeding, speed breeding, genome editing, etc. It is an important reference with special focus on accelerated development of improved forage crop varieties.Biomedical and Life Sciences SeriesPlantsDevelopmentPlant physiologyPlant biotechnologyAgriculturePlant DevelopmentPlant PhysiologyPlant BiotechnologyAgriculturePlantsDevelopment.Plant physiology.Plant biotechnology.Agriculture.Plant Development.Plant Physiology.Plant Biotechnology.Agriculture.571.82Wani Shabir Hussain1854191Gosal S. S1889794MiAaPQMiAaPQMiAaPQBOOK9911035057303321Accelerated Plant Breeding, Volume 54531128UNINA