Description
Apple Academic Electrodynamics (HB) by Megan Ferguson
Electrodynamics is a field of science involving electric current, magnetic fields, and attractive/repulsive magnetic forces. The study of generators, motors, circuitry, and electric currents all fall within this topic.Selected Contents: Introduction; Quantum-Classical Correspondence in Nonrelativistic Electrodynamics; The Geometry of Autonomous Metrical Multi-Time Lagrange Space of Electrodynamics; Born-Infeld Electrodynamics: Clifford Number and Spinor Representations; Electrodynamics of the Middle Atmosphere: Superpressure Balloon Program; Multi-scale Electrodynamics (MELD): A CAD Tool for Photonics Analysis and Design; Theoretical, Numerical and Observational Studies of Coastal Ocean Electrodynamics; Pulsar Electrodynamics: A Time-Dependent View; Electrodynamics in a Very Thin Current Sheet Leading to Magnetic Reconnection; Bactericidal Action of Positive and Negative Ions in Air; Action of Combined Magnetic Fields on Aqueous Solution of Glutamic Acid: The Further Development of Investigations; Experimental Study of Nonlinear Interaction of Plasma Flow with Charged Thin Current Sheets: Boundary Structure and Motion; Instabilities in a Thin Current Sheet and Their Consequences; From Morphology to Neural Information: The Electric Sense of the Skate; Growth of Etiolated Barley Plants in Weak Static and 50 Hz Electromagnetic Fields Tuned to Calcium Ion Cyclotron Resonance; Binary Electrokinetic Separation of Target DNA from Background DNA Primers; Transient Effect of Weak Electromagnetic Fields on Calcium Ion Concentration in Arabidopsis thaliana; Characterisation of Weak Magnetic Field Effects in an Aqueous Glutamic Acid Solution by Nonlinear Dielectric Spectroscopy and Voltammetry; The Controversy about a Possible Relationship between Mobile Phone Use and Cancer