Special Relativity

<p>Fundamentals of Special Relativity.- Introduction.- The Principle of Relativity.-&nbsp;Groups—the Galilei group.-&nbsp;Galileian law of addition of velocities.-&nbsp;The lesson from electromagnetism.-&nbsp;The postulates of Special Relativity.-&nbsp;Consequences of the postulates.-&nbsp;Conclusion.- Problems.-&nbsp;The Lorentz transformation.-&nbsp;&nbsp;Introduction.-&nbsp;The Lorentz transformation.-&nbsp;Derivation of the Lorentz transformation.- Mathematical properties of the Lorentz transformation.-&nbsp;Absolute speed limit and causality.-&nbsp;Length contraction from the Lorentz transformation.-&nbsp;Time dilation from the Lorentz transformation.-&nbsp;Transformation of velocities and accelerations in Special Relativity.-&nbsp;Matrix representation of the Lorentz transformation.-&nbsp;The Lorentz group.-&nbsp;The Lorentz transformation as a rotation by an imaginary angle with imaginary time.-&nbsp;The GPS system.-&nbsp;Conclusion.-&nbsp;Problems.-&nbsp;The 4-dimensional world view.-&nbsp;Introduction.-&nbsp;The 4-dimensional world.-&nbsp;Spacetime diagrams.-&nbsp;Conclusion.- Problems.-&nbsp;The formalism of tensors.-&nbsp;&nbsp;Introduction.-&nbsp;Vectors and tensors.-&nbsp;Contravariant and covariant vectors.-&nbsp;Contravariant and covariant tensors.-&nbsp;Tensor algebra.-&nbsp;Tensor fields.-&nbsp;Index-free description of tensors.-&nbsp;The metric tensor.-&nbsp;The Levi-Civita symbol and tensor densities.- Conclusion.- Problems.-&nbsp;Tensors in Minkowski spacetime.-&nbsp;Introduction.-&nbsp;Vectors and tensors in Minkowski spacetime.-&nbsp;The Minkowski metric.-&nbsp;Scalar product and length of a vector in Minkowski spacetime.-&nbsp;Raising and lowering tensor indices.-&nbsp;Causal nature of 4-vectors.-&nbsp;Hypersurfaces.-&nbsp;Gauss’ theorem.-&nbsp;Conclusion.- Problems.-&nbsp;Relativistic mechanics.-&nbsp;Introduction.-&nbsp;Relativistic dynamics of massive particles.-&nbsp;The relativistic force.-&nbsp;Angular momentum of a particle.-&nbsp;Particle systems.-&nbsp;Conservation of mass-energy.-&nbsp;Conclusion.- Problems.-&nbsp;Relativistic optics.-&nbsp;Introduction.-&nbsp;Relativistic optics: null rays.-&nbsp;The drag effect.-&nbsp;The Doppler effect.-&nbsp;Aberration.-&nbsp;Relativistic beaming.-&nbsp;Visual appearance of extended objects.-&nbsp;Conclusion.- Problems.-&nbsp;Measurements in Minkowski spacetime.-&nbsp;Introduction.-&nbsp;Energy of a particle measured by an observer.-&nbsp;Frequency measured by an observer.-&nbsp;A more systematic treatment of measurement.-&nbsp;The 3+1 splitting.-&nbsp;Conclusion.- Problems.-&nbsp;Matter in Minkowski spacetime.- Introduction.- The energy-momentum tensor.- Covariant conservation.- Energy conditions.- Angular momentum.- Perfect fluids.- The scalar field.- The electromagnetic field.- Conclusion.- Problems.- Special Relativity in arbitrary coordinates.- Introduction.- The covariant derivative.- Spacetime curves and covariant derivative.- Physics in Minkowski spacetime revisited.-&nbsp;Conclusions.- Problems.- Solutions to selected problems.- References.- Index.</p>