Maxwell's equations: Difference between revisions
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Maxwell's equations are named for [[James Clerk Maxwell]], whom the [[Fifth Doctor]] once identified as a friend. ([[AUDIO]]: ''[[The Haunting of Thomas Brewster (audio story)|The Haunting of Thomas Brewster]]'') | Maxwell's equations are named for [[James Clerk Maxwell]], whom the [[Fifth Doctor]] once identified as a friend. ([[AUDIO]]: ''[[The Haunting of Thomas Brewster (audio story)|The Haunting of Thomas Brewster]]'') | ||
In the real world, Maxwell's equations are a series of equations used in classical electrodynamics. Put heuristically, they can be described as saying "an electric charge generates an electric field", "there are no magnetic monopoles"(magnetic charges analogous to electric charges), "a change in a magnetic field over time creates an electric field", and "magnetic fields can be created either by a changing electric field over time or by an electric current". | In the real world, Maxwell's equations are a series of equations used in classical electrodynamics. Put heuristically, they can be described as saying "an electric charge generates an electric field", "there are no magnetic monopoles" (magnetic charges analogous to electric charges), "a change in a magnetic field over time creates an electric field", and "magnetic fields can be created either by a changing electric field over time or by an electric current". | ||
The version of these equations given in the episode are in their differential form. The variables, vectors and operators written include <span style="font-size:80%"><math>D</math></span> (the electric displacement field)<ref>https://en.wikipedia.org/wiki/Electric_displacement_field</ref>, <span style="font-size:80%"><math>\rho</math></span> (the free electric charge density)<ref>https://en.wikipedia.org/wiki/Charge_density</ref>, <span style="font-size:80%"><math>B</math></span> (the magnetic field in Teslas)<ref>https://en.wikipedia.org/wiki/Magnetic_field</ref>, <span style="font-size:80%"><math>H</math></span> (the magnetic field in <span style="font-size:50%"><math>\frac{Amperes}{m^{2}}</math></span>)<ref>https://en.wikipedia.org/wiki/Magnetic_field</ref>, and <span style="font-size:80%"><math>\nabla</math></span> (the differential operator)<ref>https://en.wikipedia.org/wiki/Nabla_symbol</ref>. In addition, the fourth equation may or may not include [https://en.wikipedia.org/wiki/Ampère%27s_circuital_law#Shortcomings_of_the_original_formulation_of_the_circuital_law Maxwell's Correction], and thus include <span style="font-size:80%"><math>J_{f}</math></span> (the free current density), all shots shown of these equations in the episode are from an angle and distance that make it impossible to tell. | The version of these equations given in the episode are in their differential form. The variables, vectors and operators written include <span style="font-size:80%"><math>D</math></span> (the electric displacement field)<ref>https://en.wikipedia.org/wiki/Electric_displacement_field</ref>, <span style="font-size:80%"><math>\rho</math></span> (the free electric charge density)<ref>https://en.wikipedia.org/wiki/Charge_density</ref>, <span style="font-size:80%"><math>B</math></span> (the magnetic field in Teslas)<ref>https://en.wikipedia.org/wiki/Magnetic_field</ref>, <span style="font-size:80%"><math>H</math></span> (the magnetic field in <span style="font-size:50%"><math>\frac{Amperes}{m^{2}}</math></span>)<ref>https://en.wikipedia.org/wiki/Magnetic_field</ref>, and <span style="font-size:80%"><math>\nabla</math></span> (the differential operator)<ref>https://en.wikipedia.org/wiki/Nabla_symbol</ref>. In addition, the fourth equation may or may not include [https://en.wikipedia.org/wiki/Ampère%27s_circuital_law#Shortcomings_of_the_original_formulation_of_the_circuital_law Maxwell's Correction], and thus include <span style="font-size:80%"><math>J_{f}</math></span> (the free current density), all shots shown of these equations in the episode are from an angle and distance that make it impossible to tell. Covariant versions of the equations would potentially be more useful to the crew of Sanctuary Base 6, being in a shorter form, but they are absent. | ||
== Footnotes == | == Footnotes == | ||
{{reflist}} | {{reflist}} | ||
[[Category:Equations]] | [[Category:Equations]] | ||
[[Category:Physics from the real world]] | [[Category:Physics from the real world]] | ||
Latest revision as of 18:25, 22 November 2023
Check the behind the scenes section, the revision history and discussion page for additional comments on this article's title.
There were equations written on a table in one of the habitation hubs of Sanctuary Base 6. (TV: The Impossible Planet)
Behind the scenes[[edit] | [edit source]]
Wiki markup needs cleaning up.
Maxwell's equations are named for James Clerk Maxwell, whom the Fifth Doctor once identified as a friend. (AUDIO: The Haunting of Thomas Brewster)
In the real world, Maxwell's equations are a series of equations used in classical electrodynamics. Put heuristically, they can be described as saying "an electric charge generates an electric field", "there are no magnetic monopoles" (magnetic charges analogous to electric charges), "a change in a magnetic field over time creates an electric field", and "magnetic fields can be created either by a changing electric field over time or by an electric current".
The version of these equations given in the episode are in their differential form. The variables, vectors and operators written include (the electric displacement field)[1], (the free electric charge density)[2], (the magnetic field in Teslas)[3], (the magnetic field in )[4], and (the differential operator)[5]. In addition, the fourth equation may or may not include Maxwell's Correction, and thus include (the free current density), all shots shown of these equations in the episode are from an angle and distance that make it impossible to tell. Covariant versions of the equations would potentially be more useful to the crew of Sanctuary Base 6, being in a shorter form, but they are absent.
