About: Classical electromagnetism and special relativity

An Entity of Type: Thing, from Named Graph: http://dbpedia.org, within Data Space: dbpedia.org

The theory of special relativity plays an important role in the modern theory of classical electromagnetism. It gives formulas for how electromagnetic objects, in particular the electric and magnetic fields, are altered under a Lorentz transformation from one inertial frame of reference to another. It sheds light on the relationship between electricity and magnetism, showing that frame of reference determines if an observation follows electrostatic or magnetic laws. It motivates a compact and convenient notation for the laws of electromagnetism, namely the "manifestly covariant" tensor form.

Property	Value
dbo:abstract	The theory of special relativity plays an important role in the modern theory of classical electromagnetism. It gives formulas for how electromagnetic objects, in particular the electric and magnetic fields, are altered under a Lorentz transformation from one inertial frame of reference to another. It sheds light on the relationship between electricity and magnetism, showing that frame of reference determines if an observation follows electrostatic or magnetic laws. It motivates a compact and convenient notation for the laws of electromagnetism, namely the "manifestly covariant" tensor form. Maxwell's equations, when they were first stated in their complete form in 1865, would turn out to be compatible with special relativity. Moreover, the apparent coincidences in which the same effect was observed due to different physical phenomena by two different observers would be shown to be not coincidental in the least by special relativity. In fact, half of Einstein's 1905 first paper on special relativity, "On the Electrodynamics of Moving Bodies," explains how to transform Maxwell's equations. (en)
dbo:thumbnail	wiki-commons:Special:FilePath/Lorentz_boost_electric_charge.svg?width=300
dbo:wikiPageID	16855603 (xsd:integer)
dbo:wikiPageLength	21955 (xsd:nonNegativeInteger)
dbo:wikiPageRevisionID	1117337641 (xsd:integer)
dbo:wikiPageWikiLink	dbr:Electric_potential dbr:Electromagnetic_field dbr:Bernhard_Riemann dbr:Antisymmetric_tensor dbr:Ricci_calculus dbr:Charge_invariance dbr:Electromagnetic_stress-energy_tensor dbr:Covariance_and_contravariance_of_vectors dbr:Annus_Mirabilis_Papers dbr:Maxwell's_equations dbr:Einstein_notation dbr:Electric_field dbr:Electromagnetic_potential dbr:Electromagnetic_tensor dbr:Free_space dbr:Galilean_non-invariance_of_classical_electromagnetism dbr:Gauss's_Law dbr:Gauss's_law_for_magnetism dbr:Levi-Civita_symbol dbr:Lorentz_transformation dbr:Magnetic_field dbr:Magnetic_vector_potential dbr:Maxwell_stress_tensor dbr:CGS dbr:Current_density dbr:Cyclic_permutation dbr:Eddy_current dbr:Faraday's_law_of_induction dbr:Four-gradient dbr:Four-vector dbr:Four-current dbr:Einstein_summation_convention dbr:Electromagnetic_field_tensor dbr:Poynting_vector dbr:International_System_of_Units dbr:Covariant_formulation_of_classical_electromagnetism dbr:Tensor dbr:Tensors dbr:Relativistic_electromagnetism dbr:Arnold_Sommerfeld dbc:Electromagnetism dbc:Special_relativity dbr:Charge_density dbr:Bivector dbr:Special_relativity dbr:Speed_of_light dbr:Classical_electromagnetism dbr:D'Alembertian dbr:Inertial_frame dbr:Natural_units dbr:Raising_and_lowering_indices dbr:Unit_vector dbr:Lorentz_factor dbr:Metric_signature dbr:The_Feynman_Lectures_on_Physics dbr:Manifestly_covariant dbr:System_of_measurement dbr:Electric_displacement dbr:Electric_permittivity dbr:Dual_tensor dbr:SI_units dbr:Ampère's_Law dbr:Four-potential dbr:Inertial_frames dbr:Minkowski_metric_tensor dbr:Manifestly-covariant dbr:Math_of_EM_field dbr:Constitutive_relations dbr:Lorenz_gauge dbr:File:Lorentz_boost_electric_charge.svg
dbp:wikiPageUsesTemplate	dbt:Electromagnetism dbt:About dbt:Cquote dbt:Equation_box_1 dbt:Main dbt:Reflist dbt:Short_description dbt:Use_American_English dbt:Paragraph
dcterms:subject	dbc:Electromagnetism dbc:Special_relativity
rdfs:comment	The theory of special relativity plays an important role in the modern theory of classical electromagnetism. It gives formulas for how electromagnetic objects, in particular the electric and magnetic fields, are altered under a Lorentz transformation from one inertial frame of reference to another. It sheds light on the relationship between electricity and magnetism, showing that frame of reference determines if an observation follows electrostatic or magnetic laws. It motivates a compact and convenient notation for the laws of electromagnetism, namely the "manifestly covariant" tensor form. (en)
rdfs:label	Classical electromagnetism and special relativity (en)
owl:sameAs	freebase:Classical electromagnetism and special relativity wikidata:Classical electromagnetism and special relativity dbpedia-fi:Classical electromagnetism and special relativity dbpedia-he:Classical electromagnetism and special relativity https://global.dbpedia.org/id/4hxzs
prov:wasDerivedFrom	wikipedia-en:Classical_electromagnetism_and_special_relativity?oldid=1117337641&ns=0
foaf:depiction	wiki-commons:Special:FilePath/Lorentz_boost_electric_charge.svg
foaf:isPrimaryTopicOf	wikipedia-en:Classical_electromagnetism_and_special_relativity
is dbo:wikiPageRedirects of	dbr:Classical_EM_and_special_relativity
is dbo:wikiPageWikiLink of	dbr:Electromagnetism dbr:Relativistic_angular_momentum dbr:Relativistic_quantum_mechanics dbr:Index_of_physics_articles_(C) dbr:Introduction_to_electromagnetism dbr:Relativistic_mechanics dbr:Lorentz_force dbr:History_of_Maxwell's_equations dbr:Covariant_formulation_of_classical_electromagnetism dbr:List_of_textbooks_in_electromagnetism dbr:Moving_magnet_and_conductor_problem dbr:Spin–orbit_interaction dbr:Classical_EM_and_special_relativity
is foaf:primaryTopic of	wikipedia-en:Classical_electromagnetism_and_special_relativity