User:John R. Brews/Sample: Difference between revisions

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''See also'' [[Help:Index/Formatting/References]]
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'''List-defined references''' (LDR) is a referencing method that moves the text of the references out of the main body of an article and into the ''References'' section at the bottom of the article.  
[[User:John R. Brews/Sample/Talk|Link to Talk page]]


LDR is a way to make referencing of article contents with a great deal less cluttering of the article's main body text in the edit page. Reduced clutter makes reading and revising text in the edit page much easier, and it also makes it possible to edit all the citations directly in the ''References'' section, instead of searching for them individually through the text. Creating LDR is not only cleaner than previous methods such as the [[Help:Index/Formatting/References|<nowiki><ref>-</ref></nowiki> method]], it is a method that will be more easily understood by new users.  
In [[physics]] and [[chemistry]], <b>charge</b> is fundamentally related to [[field]]s and [[force]]s, and is a property of pieces of matter that leads to forces between spatially separate pieces of matter that likewise manifest that particular property. There are a wide variety of such charges. In the [[Standard Model]], there are three types of charge: ''color'', ''weak isospin'' and ''weak hypercharge''.<ref name=Donoghue/>  These include the [[electric charge]] underlying [[electric current]] that enters [[Maxwell's equations]] for the [[Electromagnetism|electromagnetic field]]. In addition, there is [[mass]] that enters [[gravitation]].<ref name=Burgess/>


==Overview of how LDR works==
These charges are ''conserved'' quantities and are related to currents describing their ''flux'' or motion. The ''conservation law'' relating the charge to its current is of the form:


This section explains the steps and coding to be used in the '''''edit page''''' of a Citizendium article in order to cite references as the sources for words or statements (sentences or paragraphs) in the main body of the article.
:<math>\text{div} \mathbf J + \frac{\partial}{\partial t} \rho =0 \ , </math>


The user creates a short unique ''<font color=green>id</font>'' (identifier or name) for each individual reference which is formatted like this:
where ''div'' is the [[vector]] [[Divergence|divergence operator]], '''''J''''' is the vector current density, and ''&rho;'' is the charge density. For a volume enclosed by a surface, this equation can be expressed  by the statement that any change in the charge contained inside the closed surface is due to a current of said charge either entering or exiting through that surface.  
:<font color=green><nowiki><ref name=id/></nowiki></font> &nbsp; Note the forward slash (&thinsp;<font color=green>/</font>&thinsp;) at the end of the ''<font color=green>id</font>''.


The ''<font color=green>id</font>'' is arbitrary, but must be one word, and cannot include punctuation marks or letters like ''à'' with diacritical marks.
Such conservation laws are examples of [[Noether's theorem]], which states that every symmetry of a physical theory is related to a conservation law of this kind. This theorem is closely related to [[Curie's principle]]:
::The symmetry of an isolated system cannot decrease as the system evolves with time.<ref name=phase/>  


To cite a reference in the main body of the article, the user places <font color=green><nowiki><ref name=id/></nowiki></font> for that reference immediately to the right of the statement. The same insertion may be used in multiple locations in an article however many times that reference is needed.
The best known of these conservation laws are the conservation of momentum (the current is momentum density, the charge is mass density), related to translational symmetry of the laws of mechanics, conservation of angular momentum, related to the rotational symmetry of the laws of mechanics, and conservation of energy, related to the independence of the laws of mechanics from time translations. Such symmetries are intuitive for point particle mechanics, but for the physics of general fields some symmetries are quite non-intuitive.


Then in the ''References'' section at the bottom of the article, the user lists each reference formatted like this:
A formal description of Noether's theorem as related to charge is that a current ''j<sup>a</sup>'' = (''j<sup>a</sup><sub>0</sub>'', '''''j<sup>a</sup>''''') satisfying:
:<math>\partial^\mu j_u^a = \partial_t j_0^a + \nabla \cdot \mathbf{j}^a = 0 \ , </math>
which implies the conservation of the charge ''Q'' defined by:
:<math>Q = \int \ d^3x j_0^a \ , </math>
is a natural consequence of the ''j<sup>a</sup>'' being generators of a Lie group that is a symmetry group of the physical system.<ref name=Byers/>


:<font color=green><nowiki><ref name=id>xxxx</ref></nowiki></font> &nbsp;Where ''xxxx'' is the reference's full description. Quotation marks enclosing the ''<font color=green>id</font>'' are '''''not''''' needed.
==Charge and exchange forces==
Forces between particles are mediated by exchange of shared properties. For example, two nucleons in the same state of motion can exchange electric charge, producing an ''exchange force''. The Yukawa theory of nuclear force posited that nucleons (protons ''p'' and neutrons ''n'') could exchange electric charge by trading pions according to the reactions:<ref name= Arnikar/>


Note that the forward slash (&thinsp;<font color=green>/</font>&thinsp;) is '''''not''''' included after the ''<font color=green>id</font>'' in the ''References'' section.
:<math>n \Leftrightarrow p + \pi^-; \  p \Leftrightarrow n + \pi^+\ , </math>


===Some rules===
and forces between like particles could be introduced by exchange of zero-charge pions:


*Where the user wants to locate a reference for text that is followed by punctuation like a period or a comma, the insertion <font color=green><nowiki><ref name=id/></nowiki></font> should be located immediately to the right of that punctuation, and should be separated from the next word or next sentence by a single blank character space.
:<math> p \Leftrightarrow p + \pi^0; \ n \Leftrightarrow n + \pi^0 \ . </math>  


*In the ''References'' section, a blank line space '''must''' be provided between each listed reference.
These reactions do not conserve mass or energy, they are ''virtual reactions''. One common (although not universally accepted) "explanation" why violation is permissible is that such reactions occur very rapidly, and for very short times the energy uncertainty relation allows violation of these conservation rules.


*Note that the list in the ''References'' section is within a template. The list '''must''' start with <font color=green><nowiki>{{reflist|refs=</nowiki></font> and it '''must''' end with <font color=green><nowiki>}}</nowiki></font> exactly as shown in the example coding below.
Besides electric charge, other properties can be exchanged, such as spin (Bartlett exchange), or position (Majorana exchange).


===Putting it together===
The swapping of shared properties is a symmetry operation, the exchange of identical particles, and as such is related to conserved quantities ''via'' Noether's theorem. For example, the nucleon can be thought of as a two-state particle with an ''isospin'' that is +1/2 for a neutron and −1/2 for a proton, so the change of one to the other is an isospin exchange, and symmetry of a theory under isospin exchange indicates the theory conserves isospin.<ref name=Neuenschwander/> In a quantized version of such a theory, isospin exchange could be moderated by the pion reactions above.
To summarize, the basic templates used for bibliographic information are the same {{tl|cite book}}, {{tl|cite journal}}  and {{tl|cite web}}  templates used with the <nowiki><ref>-</ref></nowiki> method.<ref name=template  group=Notes/> However, these templates are placed ''not'' in the text, but at the end of the article following a ''References'' header using {{tl|reflist}} and the format:


:<font color=green><nowiki>{{reflist|refs=</nowiki></font> &emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;(notice the vertical separator and <font color=green>refs=</font>)
Only if isospin symmetry in the theory can be produced by a continuous transformation (one depending upon some continuously variable parameter), does it lead to an isospin current conservation law.


:<font color=green><nowiki><ref name=Ref1> {{cite book ...}} </ref></nowiki></font>&emsp; (this is first reference)
==Electrodynamics==
In electrodynamics, two types of charge are known, ''magnetic'' and ''electric''. The distinguishing property of [[electric charge]] is that electric charges can be isolated, while while an isolated magnetic charge or [[magnetic monopole]] never has been observed.<ref name=Giancoli/> Electric charges interact with magnetic charges only when in relative motion one to the other.


:<font color=green><nowiki><ref name=Ref2> {{cite book ...}} </ref></nowiki></font>&emsp; (this is second reference, <u>separated by a space</u>)
The conservation of electric charge follows directly from Maxwell's equations. It also can be derived from Noether's theorem as a result of a ''gauge invariance'' of Maxwell's theory when that theory is expressed in terms of a [[Vacuum_(quantum_electrodynamic)#Quantization_of_the_fields|vector potential]]. Although this approach has continuity with much of modern field theory, it is somewhat unintuitive, as the "symmetry" of the recast Maxwell equations is simply due to introduction of a mathematical device that adds an unnecessary degree of freedom into the formulation thereby introducing this symmetry artificially.<ref name=Stamatescu/> Below is a digression on this topic.
:The basic electric field '''''E''''' and magnetic field '''''B''''' of Maxwell's equations can be replaced by introduction of a ''scalar potential'' ''&phi;'' and a ''vector potential'' '''''A''''' using the relations:
:::<math>\boldsymbol E = -\nabla \phi -\frac{\partial }{\partial t} \boldsymbol A , </math>
:::<math>\boldsymbol B = -\nabla \times \boldsymbol A . </math>
:Although the potentials uniquely determine the fields, the reverse is not true. Different potentials produce the same fields; in particular the potentials denoted by primes below produce the same fields:
:::<math>\phi' = \phi +\frac{\partial }{\partial t} \Gamma , </math>
:::<math>\boldsymbol A' = \boldsymbol A  -\nabla \Gamma  . </math>
:Here ''&Gamma; = &Gamma;('''r''', t)'' is any continuous function of the space-time coordinates '''''r''''', ''t''. Consequently, a theory based upon potentials instead of fields has the additional symmetry that it is unchanged by substitution of primed potentials instead of the original potentials. This change of potentials from unprimed to primed is called a ''gauge transformation'' and this new symmetry leads directly to the continuity equation for electric charge:
:::<math>\nabla \boldsymbol  \cdot J + \frac{\partial }{\partial t} \rho = 0 \ .</math>
:This equation is a direct consequence of the Maxwell equations defining charge and current densities (in Heaviside-Lorentz units):
:::<math>\nabla \cdot \boldsymbol E = \rho \ , </math>
:::<math>\nabla \times \boldsymbol B -\frac{\partial }{\partial t}\boldsymbol E = \boldsymbol J \ . </math>
:However, using the potential formulation, the continuity equation is required if the theory is to be gauge invariant,<ref name=Cottingham/> and this requirement is consistent with Noether's theorem.


:<font color=green><nowiki>}}</nowiki></font>&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;&emsp;(these are additional final braces)
In a [[Quantization of the electromagnetic field|quantized theory]] based upon the potential formulation of Maxwell's equations, the electrical force between charged particles is an exchange force mediated by trading charge-neutral [[photon]]s. The electromagnetic potentials exist as vibrations with certain allowed amplitudes determined by the number of photons employed, and field amplitudes are increased or decreased by adding or subtracting photons. Thus, the force exerted upon a charged particle as determined by the field it experiences, depends upon the number of photons in the corresponding potentials.


where the names "Ref1", "Ref2" are arbitrary creations of the writer. Connection to these definitions from the text is done with an insertion, such as <font color=green><nowiki><ref name=Ref1/></nowiki></font>, but notice, with a forward slash.
==Weak forces==
Weak forces are mediated by the electric charged ''W<sup>+</sup>'' and ''W<sup>−</sup>'' particles and the electric charge neutral ''Z<sup>0</sup>'' particle, all with spin 1. The weak interaction is of short range, being effective over a distance of approximately 10<sup>−3</sup> fm. Analysis of the weak force parallels that of the electromagnetic force, apart from the huge mass of the exchanged particles compared to the photon. The "weak force" charge introduced that couples to this force is called ''flavor''.<ref name=Tipler/> It is customaryu to refer to lepton flavor, rather than lepton charge, and individual lepton flavors are attributed to each family: electron flavor ''L<sub>e</sub>'' for electrons; muon flavor ''L<sub>&mu;</sub>'' for muons; tau flavor ''L<sub>&tau;</sub>'' for taus.<ref name=Boyarkin/> p. 38
However, the terminology is somewhat confused. Some authors do refer to both "weak charge" and to "lepton flavor".<ref name=Nagashima/> The issue may be that quarks and leptons behave differently under the weak force?


Although not necessary to its functionality, for ease in editing, the list of named notes in the ''References'' section can be put in alphabetical order. That makes finding the note in this list easier in the event the note should be edited, for example to update a link or add to descriptive material.
==Nuclear forces==
In 1935 [http://www.nobelprize.org/nobel_prizes/physics/laureates/1949/yukawa-bio.html Yukawa] invented the [[meson]] theory for explaining the forces holding atomic nucleii together, an assemblage of neutrons and protons. The theory led to the experimental observation of the [[pion]] or &pi;-meson and the [[muon]] or &mu;-meson. The behavior of nuclear forces was explained as an exchange of mesons. Today, mesons are considered to be quark-antiquark pairs, and a more refined theory of nuclear interactions is based upon [[quantum chromodynamics]]. Nuclear forces are not considered fundamental today, but are a consequence of the underlying ''strong forces'' between quarks, also called chromodynamic forces or color forces. On that basis, nuclear forces are an exchange force fundamentally based upon color, and only approximated by the Yukawa theory.


==Example==
==Chromodynamics==
In the [[Standard Model]] of particle physics, [[quantum chromodynamics]] describes the ''strong force'', also called the ''color force'' or ''chromo force'', and relates it to the '''color charge''' as a property of [[quark]]s and [[gluon]]s.<ref name=Webb/> Similar to magnetic charge, ''color'' is not seen directly, as all observable particles have no overall color.<ref name=Watson/>  As with electric and magnetic charge, color charge can be multiple valued, conventionally called ''red, green'' or ''blue''.  Color charge is not assigned a numerical value; however, a superposition in equal amounts of all three colors leads to a "neutral" color charge, a somewhat stretched analogy with the superposition of red, green and blue light to produce white light.<ref name=Han/> Thus, protons and neutrons, which consist of three quarks with all three colors are color-charge neutral. Quark combinations are held together by exchange of combinations of eight different [[gluon]]s that also are color charged.<ref name=Rosen/><ref name=Gothard/><ref name=Greenberger/><ref name=Greenberg/>


'''''This is how to code the edit page of an article using "List-Defined References"&thinsp;:'''''
The color charges of ''anti''quarks are ''anti''colors. The combination of a quark and an antiquark to form a [[meson]], such as a [[pion]], [[kaon]] and so forth, leads to a neutral color charge.
:{|cellpadding=8 align=center style="background:#fffaf5; width:99%; border:1px dotted; margin:5px;"


|The '''Sun''' is the dwarf star<font color=green><nowiki><ref name=Weissman2007p71/></nowiki></font> at the center of the Solar System. There are eight major planets and other celestial bodies orbiting it.<font color=green><nowiki><ref name=Weissman2007p3/></nowiki></font> It is extremely hot, with surface temperatures in excess of 6,000 K and a central core temperature of about 15,700,000 K.<font color=green><nowiki><ref name=Weissman2007p72/></nowiki></font>
==Other charges==
The charges above are related to fields and forces and to a ''local'' (coordinate dependent) Noether's theorem. Other charges are known, however, that are connected to ''global'' or ''discrete'' symmetries (no continuous parametric dependence, such as a coordinate dependence) and so to a global Noether's theorem, and have no relation to forces or fields.


Since the Sun is about 150,000,000 kilometers away,<font color=green><nowiki><ref name=Weissman2007p72/></nowiki></font> only a very small amount of its heat and light reach the Earth. By contrast, the Earth's Moon is very much smaller and very much colder.<font color=green><nowiki><ref name=Vasavada1999/></nowiki></font>
One such charge in elementary particle theory is the '''baryonic charge''', ''B'', also referred to as a ''number'', with value +1 for all baryons (notably, neutrons and protons, but also others like the &Lambda; and &Sigma; particles) and −1 for all ''anti''baryons and zero for non-baryons. Quarks are an exception, and have a baryon number of 1/3. Unlike electric charge, which serves as a source for the [[Maxwell's equations|electromagnetic field]], baryon charge is not related to an associated "baryonic" field.<ref name=Boyarkin/>


<nowiki>==References==</nowiki>
Finally, we mention the '''leptonic charge''' (also called lepton ''number'') carried by [[lepton]]s: electrons, muons, taus, and their associated [[neutrino]]s.<ref name=Han/> Lepton charge depends upon the ''flavor'' of the lepton<ref name=Tipler/> ''L<sub>e</sub>, L<sub>&mu;</sub>, L<sub>&tau;</sub>'' with values +1 for the electron, muon and tau meson, and −1 for their antiparticles.<ref name=Boyarkin/> The ''total'' lepton number ''L'' of a complex is:
:<math>L=\sum_{j=e,\mu,\tau} L_j \ . </math>


<font color=green><nowiki>{{reflist|refs=</nowiki></font>
Non-leptons have a total lepton number ''L'' of zero. Within the Standard Model, lepton number is conserved for strong and electromagnetic interactions; however, it is not necessarily conserved in weak particle reactions.<ref name=Boyarkin/><ref name=Quinn/>


<font color=green><nowiki><ref name=Vasavada1999>{{</nowiki></font> cite journal | author=Ashwin R. Vasavadaa, David A. Paige and Stephen E. Wood | title= Near-Surface Temperatures on Mercury and the Moon and the Stability of Polar Ice Deposits | journal= Icarus | volume=141 | issue=2 |pages=pp. 179-193 | date= October 1999 |doi=10.1006/icar.1999.6175 <font color=green><nowiki>}}</ref></nowiki></font><br/>
==References==
{{reflist|refs=
<ref name= Arnikar>
{{cite book |title=Essentials of nuclear chemistry |author=Hari Jeevan Arnikar |url=http://books.google.com/books?id=C88GMy-p0AwC&pg=PA16 |pages=p. 16 ''ff'' |isbn=8122407129 |year=1995 |publisher=New Age International |edition=4th ed}}
 
</ref>
 
<ref name=Boyarkin>
{{cite book |title=Introduction to Physics of Elementary Particles |author=O. M. Boyarkin|editor=O. M. Boyarkin, Alfred L. Heinzerton, eds |url=http://books.google.com/books?id=WFDs_SJgILQC&pg=PA37 |chapter=Chapter 3: Leptons and hadrons |pages=pp. 37-40 |isbn=160021200X |year=2007 |publisher=Nova Publishers}}
 
</ref>
 
<ref name=Byers>
{{cite web |title=The Life and Times of Emmy Noether: Contributions of Emmy Noether to Particle Physics |url=http://www.physics.ucla.edu/~cwp/articles/9411110.pdf |author=Nina Byers |year=1994 |publisher=UCLA/94/TEP/42; hep-th/9411110}} Presented at the International Conference on THE HISTORY OF ORIGINAL IDEAS AND
BASIC DISCOVERIES IN PARTICLE PHYSICS, Erice, Italy, 29 July - 4 August 1994.
</ref>
 
<ref name=Burgess>
{{cite book |title=Classical covariant fields |author=Mark Burgess |url=http://books.google.com/books?id=8k3NY53iMgsC&pg=PA325 |pages=pp. 325 ''ff'' |chapter=Chapter 12: Charge and current |isbn= 0521813638 |year=2004 |publisher=Cambridge University Press}}
</ref>
 
<ref name=Cottingham>
{{cite book |title=An introduction to the Standard Model of particle physics |author=WN Cottingham, DA Greenwood |isbn=978-0-521-85249-4 |year=2007 |edition=2nd ed |publisher=Cambridge University Press |chapter=Gauge transformations |pages=p. 41 |url=http://books.google.com/books?id=Dm36BYq9iu0C&pg=PA41}}
</ref>
 
<ref name=Donoghue>
{{cite book |title=Dynamics of the standard model |author=John F. Donoghue, Eugene Golowich, Barry R. Holstein |url=http://books.google.com/books?id=hFasRlkBbpYC&pg=PA24 |pages=p. 24 |isbn= 0521476526 |year=1994 |publisher=Cambridge University Press}}
</ref>  
 
<ref name=Giancoli>
 
{{cite book |title=Physics for scientists and engineers with modern physics |author=Douglas C. Giancoli |url=http://books.google.com/books?id=xz-UEdtRmzkC&pg=PA708 |pages=p. 708 |isbn=0132273594 |publisher=Pearson Education |edition=4rth ed}}
</ref>


<font color=green><nowiki><ref name=Weissman2007p3>{{</nowiki></font> cite book | author=Paul R Weissman |url=http://books.google.com/books?id=G7UtYkLQoYoC&pg=PA3 | title=Encyclopedia of the solar system |chapter=Chapter 1: The solar system and its place in the galaxy| edition= 2nd Edition |editor=Lucy-Ann McFadden, Paul Robert Weissman, Torrence V. Johnson, editors | publisher=Academic Press | year=2007 | pages= pp. 3 ''ff'' |isbn= 0120885891 <font color=green><nowiki>}}</ref></nowiki></font>  
<ref name=Gothard>


<font color=green><nowiki><ref name=Weissman2007p71>{{</nowiki></font> cite book | author=Markus J Aschwanden |url=http://books.google.com/books?id=G7UtYkLQoYoC&pg=PA71 | title=Encyclopedia of the solar system |chapter=Chapter 4: The Sun | edition= 2nd Edition |editor=Lucy-Ann McFadden, Paul Robert Weissman, Torrence V. Johnson, editors | publisher=Academic Press | year=2007 | pages= pp. 71 ''ff'' | isbn= 0120885891 <font color=green><nowiki>}}</ref></nowiki></font>
{{cite book |title=Encyclopedia of Physical Science, Volume 1 |author=Joe Rosen, Lisa Quinn Gothard |url=http://books.google.com/books?id=avyQ64LIJa0C&pg=PA278 |pages=p. 278 |isbn=0816070113 |year=2009 |publisher=Infobase Publishing}}


<font color=green><nowiki><ref name=Weissman2007p72>{{</nowiki></font> cite book | author=Markus J Aschwanden |url=http://books.google.com/books?id=G7UtYkLQoYoC&pg=PA72 | title=Encyclopedia of the solar system |chapter=Table 1: Basic physical properties of the sun | edition= 2nd Edition |editor=Lucy-Ann McFadden, Paul Robert Weissman, Torrence V. Johnson, editors | publisher=Academic Press | year=2007 | pages= p. 72 | isbn= 0120885891 <font color=green><nowiki>}}</ref></nowiki>
</ref>


}}</font>
<ref name=Greenberg>
{{cite journal |title=The color charge degree of freedom in particle physics |author=OW Greenberg |url=http://arxiv.org/abs/0805.0289v2  |year=2008 }} Chapter in ''Greenberger et al.'' below.


|}
</ref>


<ref name=Greenberger>


'''''This is what the above coding produces on the article page&thinsp;:'''''
{{cite book |title=Compendium of Quantum Physics: Concepts, Experiments, History and Philosophy |chapter=Quantum chromodynamics (QCD)  |editor=Daniel M. Greenberger, Klaus Hentschel, Friedel Weinert |url=http://books.google.com/books?id=ekyAV8VtfuYC&pg=PA525 |pages=pp. 524 ''ff'' |isbn=3540706224 |year=2009 |publisher=Springer}}


:{|cellpadding=8 align=center style="background:#fffaf5; width:99%; border:1px dotted; margin:5px;"
</ref>


|The '''Sun''' is the dwarf star<ref name=Weissman2007p71/> at the center of the Solar System. There are eight major planets and other celestial bodies orbiting it.<ref name=Weissman2007p3/> It is extremely hot, with surface temperatures in excess of 6,000 K and a central core temperature of about 15,700,000 K.<ref name=Weissman2007p72/>
<ref name=Han>


Since the Sun is about 150,000,000 kilometers away,<ref name=Weissman2007p72/> only a very small amount of its heat and light reach the Earth. By contrast, the Earth's Moon is very much smaller and very much colder.<ref name=Vasavada1999/>
{{cite book |title=Quarks and gluons: a century of particle charges |author=M. Y. Han |url=http://books.google.com/books?id=LBb3z_-qPFoC&pg=PA116 |pages=p. 116 |isbn=9810237456 |publisher=World Scientific |year=1999}}


'''<big>References</big>'''
</ref>


{{reflist|refs=
<ref name=Nagashima>
{{cite book |author=Yorikiyo Nagashima, Yoichiro Nambu |url=http://books.google.com/books?id=J0l8s3pdOksC&pg=PA554 |pages=p. 554 |title=Elementary Particle Physics: Volume 1: Quantum Field Theory and Particles, Volume 1 |publisher=Wiley-VCH |year=2010 |isbn=3527409629}}
</ref>
 
<ref name=Neuenschwander>
{{cite book |title=Emmy Noether's Wonderful Theorem |url=http://books.google.com/books?id=QeZaVQWRnuQC&pg=PA192 |pages=p. 192 ''ff'' |chapter=§9.1 Conservation of properties and unitary transformations |author=Dwight E. Neuenschwander |isbn=0801896940 |year=2010 |publisher=The Johns Hopkins University Press}}
</ref>


<ref name=Vasavada1999>{{cite journal | author=Ashwin R. Vasavadaa, David A. Paige and Stephen E. Wood | title= Near-Surface Temperatures on Mercury and the Moon and the Stability of Polar Ice Deposits | journal= Icarus | volume=141 | issue=2 |pages=pp. 179-193 | date= October 1999 |doi=10.1006/icar.1999.6175}}</ref>
<ref name=phase>
Some care is needed in looking at this principle because of the phenomenon of [[spontaneous symmetry breaking]]. For example, as a cubic ferroelectric material like BaTiO<sub>3</sub> is cooled below its Curie point, its cubic symmetry is replaced by a tetragonal ferroelectric symmetry as the frequency corresponding to a  tetragonal elastic distortion tends to zero ([[Goldstone's theorem]]). The overall cubic symmetry of the crystal is retained because the crystal breaks into finite domains, each with a differently oriented tetragonal axis, so that ''statistically'' the symmetry of an infinite crystal still is cubic. For a general discussion, see {{cite book |title=Symmetry breaking |author=F. Strocchi |url=http://books.google.com/books?id=tPOcCWjvUK8C&printsec=frontcover |isbn=3540735925 |year=2008 |edition=2nd ed |publisher=Springer}}
</ref>


<ref name=Weissman2007p3>{{cite book | author=Paul R Weissman |url=http://books.google.com/books?id=G7UtYkLQoYoC&pg=PA3 | title=Encyclopedia of the solar system |chapter=Chapter 1: The solar system and its place in the galaxy| edition= 2nd Edition |editor=Lucy-Ann McFadden, Paul Robert Weissman, Torrence V. Johnson, editors | publisher=Academic Press | year=2007 | pages= pp. 3 ''ff'' | isbn= 0120885891}}</ref>
<ref name=Quinn>
{{cite book |title=The Mystery of the Missing Antimatter |author=Helen R. Quinn, Yossi Nir |url=http://books.google.com/books?id=W_E2rAui1l8C&pg=PA130 |pages=p. 130 |chapter=Chapter 12: Baryon and Lepton number conservation? |publisher=Princeton University Press |year=2010 |isbn=1400835712}}
 
</ref>


<ref name=Weissman2007p71>{{cite book | author=Markus J Aschwanden |url=http://books.google.com/books?id=G7UtYkLQoYoC&pg=PA71 | title=Encyclopedia of the solar system |chapter=Chapter 4: The Sun | edition= 2nd Edition |editor=Lucy-Ann McFadden, Paul Robert Weissman, Torrence V. Johnson, editors | publisher=Academic Press | year=2007 | pages= pp. 71 ''ff'' | isbn= 0120885891}}</ref>
<ref name=Rosen>


<ref name=Weissman2007p72>{{cite book | author=Markus J Aschwanden |url=http://books.google.com/books?id=G7UtYkLQoYoC&pg=PA72 | title=Encyclopedia of the solar system |chapter=Table 1: Basic physical properties of the sun | edition= 2nd Edition |editor=Lucy-Ann McFadden, Paul Robert Weissman, Torrence V. Johnson, editors | publisher=Academic Press | year=2007 | pages= p. 72 | isbn= 0120885891}}</ref>
{{cite book |title=Encyclopedia of physics |author=Joe Rosen |url=http://books.google.com/books?id=HQWNJyRV6kMC&pg=PA85 |pages=p. 85 |isbn=0816049742 |publisher=Infobase Publishing |year=2004}}  


}}
</ref>
|}


Additional examples can be seen in the article [[Set (mathematics)]], which is formatted using the ''CZ:List-defined references'' methodology. The article [[Coriolis force]] also is formatted using the ''CZ:List-defined references'' method, but using the template {{tl|reflist2}}, which works in exactly the same way, but results in a two-column format for the reference listing.
<ref name=Stamatescu>
{{cite book |title=Approaches to fundamental physics: an assessment of current theoretical ideas |author=K.-H. Rehren, E Seiler |editor=Ion-Olimpiu Stamatescu, Erhard Seiler, eds |quote=Gauge symmetry was originally observed within Maxwell's theory of classical electrodynamics as an ambiguity related to the artificial introduction of unobservable potentials in order to solve two of Maxwell's four equations. |url=http://books.google.com/books?id=2Vpa6PxOs9IC&pg=PA401 |pages=p. 401 |isbn=3540711155 |year=2007 |publisher=Springer}}
</ref>


===A style note===
<ref name=Tipler>


Note that the {{tl|cite book}} and {{tl|cite journal}} templates used in the above coding example are formatted with the cells in a horizontal style rather than a vertical style where the cells are in a vertical column. The horizontal style looks neater and definitely uses less space. However, the horizontal style is only a suggestion, it is not mandatory.
{{cite book |title=Physics for scientists and engineers: Elementary modern physics, Volume 3 |author=Paul Allen Tipler |chapter=Summary table |pages=p. 1409 |url=http://books.google.com/books?id=i58oVr_Mbs4C&pg=PA1409 |isbn=1429201347 |edition=6th ed |publisher=Macmillan |year=2007}}
 


The information fields in the templates do not have to be filled in in any particular order (the template puts them in standard order automatically), and fields can be left blank. For readers looking for sources, the ''url'' links that the template imbeds in the titles of books and papers are helpful, and ''isbn'' or ''doi'' entries will assist readers even if the ''url'' links expire.
</ref>


Of course, in the ''References'' section one just can type in the information ''<font color=green>xxx</font>'' in <font color=green><nowiki><ref name = MyRefName></nowiki>&ensp;''xxx''&ensp;<nowiki></ref></nowiki></font>, but an alternative is to copy and paste one of the listings below and fill it in by copying and pasting the information.
<ref name=Watson>
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{{tl|cite book}} &emsp;
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One fills in the fields one wants to use, and leaves the rest blank. Other fields can be found in [[CZ:Citation templates]].
{{cite book |title=The quantum quark |author=Andrew Watson |url=http://books.google.com/books?id=ip50x8IOfnEC&pg=PA170 |pages=pp. 170 ''ff'' |isbn=0521829070 |year=2004 |publisher=Cambridge University Press}}


==Notes==
</ref>
{{Reflist|group=Notes|refs=


<ref name=template group=Notes> For details and other templates, see [[CZ:Citation templates]]</ref>
<ref name=Webb>


{{cite book |title=Out of this world: colliding universes, branes, strings, and other wild ideas of modern physics |url=http://books.google.com/books?id=3AJdTYu3m5sC&pg=PA190 |pages=p. 190 |isbn=0387029303 |author=Stephen Webb |publisher=Springer |year=2004}}
</ref>
}}
}}
==miscellaneous==
*[http://www.amazon.com/Quantum-Mathematicians-Encyclopedia-Mathematics-Applications/dp/052163265X#reader_052163265X Noether's theorem]
*[http://books.google.com/books?id=htJbAf7xA_oC&pg=PA278&dq=weak+isospin&hl=en&ei=lc5kTrC_BungiAKu9YioCg&sa=X&oi=book_result&ct=result&resnum=2&ved=0CDIQ6AEwAQ#v=onepage&q=weak%20isospin&f=false essay on charge]
*[http://books.google.com/books?id=AwhkM6hVj-wC&pg=PA6&dq=this+invariance+%22Quantum+electrodynamics+possesses%22&hl=en&ei=8vRbTrCrNKnRiAKg86TvDg&sa=X&oi=book_result&ct=result&resnum=1&ved=0CCoQ6AEwAA#v=onepage&q=this%20invariance%20%22Quantum%20electrodynamics%20possesses%22&f=false gauge theory]
*[http://books.google.com/books?id=cDJw3dWjw_UC&pg=PA208&dq=photon+exchange+force+Noether&hl=en&ei=C_JbTvuWIOfSiAKd27TtDg&sa=X&oi=book_result&ct=result&resnum=2&ved=0CDIQ6AEwATgK#v=onepage&q&f=false symmetry breaking]
*[http://books.google.com/books?id=YPz2KsNBrz4C&pg=PA39&dq=photon+exchange+force+Noether&hl=en&ei=vu9bTsKDDarQiAK4kaDbDg&sa=X&oi=book_result&ct=result&resnum=10&ved=0CF8Q6AEwCQ#v=onepage&q&f=false gauge theory]
*[http://www.physics.wustl.edu/~alford/p551/noether.pdf derivation of Noether from change in lagrangian]
*[http://books.google.com/books?id=0AroLuyXAX0C&pg=PA11&dq=photon+exchange+force+Noether&hl=en&ei=vu9bTsKDDarQiAK4kaDbDg&sa=X&oi=book_result&ct=result&resnum=9&ved=0CFoQ6AEwCA#v=onepage&q=photon%20exchange%20force%20Noether&f=false Lagrangian is a function of the symmetry current]
*[http://www.amazon.com/Theoretical-Nuclear-Subnuclear-Physi-Walecka/dp/9812388982#reader_9812388982 Lagrangian of QCD and Noether's theorem]
*[http://books.google.com/books?id=ip50x8IOfnEC&pg=PA58&dq=photon+exchange+force&hl=en&ei=--lbTpzVAaXQiAKI2InEDg&sa=X&oi=book_result&ct=result&resnum=7&ved=0CEsQ6AEwBg#v=onepage&q=photon%20exchange%20force&f=false exchange forces]
*[http://books.google.com/books?id=0QyQC9cvhtMC&pg=PA66&dq=photon+exchange+force&hl=en&ei=--lbTpzVAaXQiAKI2InEDg&sa=X&oi=book_result&ct=result&resnum=8&ved=0CFAQ6AEwBw#v=onepage&q=photon%20exchange%20force&f=false derive Coulomb's law as an exchange]
*[http://books.google.com/books?id=6-7TE5N0vbIC&pg=PA23&dq=lepton+flavor+charge&hl=en&ei=En1ZTtroO_PSiAK6rtjDCQ&sa=X&oi=book_result&ct=result&resnum=6&ved=0CEgQ6AEwBTgK#v=onepage&q=lepton%20flavor%20charge&f=false flavor not conserved]
*[http://books.google.com/books?id=6-7TE5N0vbIC&pg=PA23&dq=lepton+flavor+charge&hl=en&ei=En1ZTtroO_PSiAK6rtjDCQ&sa=X&oi=book_result&ct=result&resnum=6&ved=0CEgQ6AEwBTgK#v=onepage&q=lepton%20flavor%20charge&f=false three coupling constants: &alpha;, &alpha;<sub>s</sub>, &alpha;<sub>W</sub>]
*[http://books.google.com/books?id=tpU18JqcSNkC&pg=PA656&dq=lepton+flavor+charge&hl=en&ei=En1ZTtroO_PSiAK6rtjDCQ&sa=X&oi=book_result&ct=result&resnum=4&ved=0CD0Q6AEwAzgK#v=onepage&q=lepton%20flavor%20charge&f=false weak charge also called flavor charge]
*[http://books.google.com/books?id=wJUDIBstnMQC&pg=PA37&dq=lepton+number&hl=en&ei=Bm9ZTqjZKNHXiAL9s72uCQ&sa=X&oi=book_result&ct=result&resnum=2&ved=0CDMQ6AEwAQ#v=onepage&q=lepton%20number&f=false lepton and baryon number]
*[http://books.google.com/books?id=w9Dz56myXm8C&pg=PA353&dq=introduces+the+gauge+theories+that+describe&hl=en&ei=H1FZTvfWBMbSiAKv2anJCQ&sa=X&oi=book_result&ct=result&resnum=1&ved=0CC0Q6AEwAA#v=onepage&q=introduces%20the%20gauge%20theories%20that%20describe&f=false Griffiths: gauge theories]
*[http://books.google.com/books?id=HNcQ_EiuTxcC&pg=PA165&dq=the+phase+is+just+the+gauge+function&hl=en&ei=9U9ZTobpJKjYiALJ0qnPCQ&sa=X&oi=book_result&ct=result&resnum=7&ved=0CEoQ6AEwBg#v=onepage&q=the%20phase%20is%20just%20the%20gauge%20function&f=false the phase is just the gauge function]
*[http://books.google.com/books?id=jPEkmI2TLnkC&pg=PA6&dq=introduces+the+gauge+theories+that+describe&hl=en&ei=0lFZToe2AebViAKfucWkCQ&sa=X&oi=book_result&ct=result&resnum=2&ved=0CDAQ6AEwATgK#v=onepage&q&f=false Gauge field interactions]
*[http://books.google.com/books?id=IcL31owjU3gC&pg=PA126&dq=conserved+generator+current&hl=en&ei=SB5VTrfMKIXPiALbrN3wDA&sa=X&oi=book_result&ct=result&resnum=9&ved=0CFQQ6AEwCDge#v=onepage&q=conserved%20generator%20current&f=false generators of group induced by a current are charges]
*[http://books.google.com/books?id=IcL31owjU3gC&pg=PA129&dq=conserved+generator+current&hl=en&ei=SB5VTrfMKIXPiALbrN3wDA&sa=X&oi=book_result&ct=result&resnum=9&ved=0CFQQ6AEwCDge#v=onepage&q=conserved generator current&f=false does a conserved current imply a symmetry?] p. 129
*[http://books.google.com/books?id=n8Mmbjtco78C&pg=PA77  Noether current; basics]
*[http://books.google.com/books?id=J0l8s3pdOksC&pg=PA731&dq=conserved+generator+current&hl=en&ei=ER1VTtfZJKHjiAKdpOjFDA&sa=X&oi=book_result&ct=result&resnum=10&ved=0CFgQ6AEwCTgU#v=onepage&q=conserved%20generator%20current&f=false basics again]
*[http://books.google.com/books?id=J0l8s3pdOksC&pg=PA733&dq=conserved+generator+current&hl=en&ei=ER1VTtfZJKHjiAKdpOjFDA&sa=X&oi=book_result&ct=result&resnum=10&ved=0CFgQ6AEwCTgU#v=onepage&q=conserved%20generator%20current&f=false conserved quantities and forces]
*[http://books.google.com/books?id=oQn5ybiQKAoC&pg=PA676&dq=conserved+generator+current&hl=en&ei=SB5VTrfMKIXPiALbrN3wDA&sa=X&oi=book_result&ct=result&resnum=1&ved=0CCkQ6AEwADge#v=onepage&q=conserved%20generator%20current&f=false conservation of current]
*[http://books.google.com/books?id=n8Mmbjtco78C&pg=PA79&dq=conserved+generator+current&hl=en&ei=ZBlVTvG2KcXjiAKchKTyDA&sa=X&oi=book_result&ct=result&resnum=10&ved=0CFkQ6AEwCQ#v=onepage&q=conserved%20generator%20current&f=false Zee]
*[http://books.google.com/books?id=LCInXoalY2wC&pg=PA316&dq=conserved+generator+current&hl=en&ei=ZBlVTvG2KcXjiAKchKTyDA&sa=X&oi=book_result&ct=result&resnum=8&ved=0CE8Q6AEwBw#v=onepage&q=conserved%20generator%20current&f=false Noether current]
*[http://books.google.com/books?id=ZtthVxxc3SkC&pg=PA59&dq=conserved+generator+current&hl=en&ei=ER1VTtfZJKHjiAKdpOjFDA&sa=X&oi=book_result&ct=result&resnum=1&ved=0CCkQ6AEwADgU#v=onepage&q=conserved%20generator%20current&f=false formal math statement]
*[http://books.google.com/books?id=YgkfZgFdui8C&pg=PA188&dq=vector+current+coupling&hl=en&ei=ABhVToDxBuPjiAL_3JXrDA&sa=X&oi=book_result&ct=result&resnum=3&ved=0CDQQ6AEwAg#v=onepage&q=vector%20current%20coupling&f=false conserved vector current]
*[http://books.google.com/books?id=Lxr2S-zjOgYC&pg=PA358&dq=weak+isospin+hypercharge+electric&hl=en&ei=5xFVTunTJ4PYiALz57X3DA&sa=X&oi=book_result&ct=result&resnum=4&ved=0CDwQ6AEwAw#v=onepage&q=weak%20isospin%20hypercharge%20electric&f=false coupling factors e, gI, gY]
*[http://books.google.com/books?id=hFasRlkBbpYC&pg=PA53&dq=weak+isospin+hypercharge+electric&hl=en&ei=5xFVTunTJ4PYiALz57X3DA&sa=X&oi=book_result&ct=result&resnum=3&ved=0CDUQ6AEwAg#v=onepage&q=weak%20isospin%20hypercharge%20electric&f=false Donoghue on charge]
*[http://books.google.com/books?id=wez0SGmemagC&pg=PA99&dq=weak+isospin+hypercharge+electric&hl=en&ei=5xFVTunTJ4PYiALz57X3DA&sa=X&oi=book_result&ct=result&resnum=1&ved=0CCoQ6AEwAA#v=onepage&q=weak%20isospin%20hypercharge%20electric&f=false Dodd on charge]
*[http://books.google.com/books?id=w9Dz56myXm8C&pg=PA344&dq=weak+isospin+hypercharge+electric&hl=en&ei=5xFVTunTJ4PYiALz57X3DA&sa=X&oi=book_result&ct=result&resnum=2&ved=0CDAQ6AEwAQ#v=onepage&q=weak%20isospin%20hypercharge%20electric&f=false Griffiths on charge]
*[http://books.google.com/books?id=ZdaE2agLxY8C&pg=PA1&dq=electric+charge+electroweak&hl=en&ei=uw1VTrG3IbHSiAKahtXcDA&sa=X&oi=book_result&ct=result&resnum=2&ved=0CDAQ6AEwAQ#v=onepage&q=electric%20charge%20electroweak&f=false charges]
*[http://books.google.com/books?id=WFDs_SJgILQC&pg=PA38&dq=lepton+charge&hl=en&ei=vDtJTqDsOePKiALM6vDsAQ&sa=X&oi=book_result&ct=result&resnum=4&ved=0CD8Q6AEwAw#v=onepage&q=lepton%20charge&f=false lepton flavor, not lepton charge]
*[http://books.google.com/books?id=cOnjDfQQX0UC&pg=PA332&dq=lepton+charge&hl=en&ei=vDtJTqDsOePKiALM6vDsAQ&sa=X&oi=book_result&ct=result&resnum=1&ved=0CC4Q6AEwAA#v=onepage&q=lepton%20charge&f=false Rowlands]
*[http://books.google.com/books?id=c60mCxGRMR8C&pg=PA892&dq=lepton+charge&hl=en&ei=vDtJTqDsOePKiALM6vDsAQ&sa=X&oi=book_result&ct=result&resnum=2&ved=0CDMQ6AEwAQ#v=onepage&q=lepton%20charge&f=false Harris]
*[http://books.google.com/books?id=P_T0xxhDcsIC&pg=PA127&dq=lepton+charge&hl=en&ei=vDtJTqDsOePKiALM6vDsAQ&sa=X&oi=book_result&ct=result&resnum=3&ved=0CDoQ6AEwAg#v=onepage&q=lepton%20charge&f=false Schutz]
*[http://books.google.com/books?id=krTli3-XL4AC&pg=PA495&dq=color+chromodynamic+force&hl=en&ei=hh9NTp2VDpPKiALc5JiFAQ&sa=X&oi=book_result&ct=result&resnum=4&ved=0CDkQ6AEwAw#v=onepage&q=color%20chromodynamic%20force&f=false Bord]
*[http://books.google.com/books?id=w9Dz56myXm8C&pg=PA67&dq=color+chromodynamic+force&hl=en&ei=hh9NTp2VDpPKiALc5JiFAQ&sa=X&oi=book_result&ct=result&resnum=5&ved=0CD8Q6AEwBA#v=onepage&q=color%20chromodynamic%20force&f=false Griffiths]
*[http://arxiv.org/PS_cache/arxiv/pdf/0901/0901.1903v1.pdf QCD]
*[http://books.google.com/books?id=8TxnB4uGUxkC&pg=SA36-PA26&dq=pion+pion+color+dipole+interaction&hl=en&ei=mBZhTrLOKY_YiAK0wN24Dg&sa=X&oi=book_result&ct=result&resnum=6&ved=0CEIQ6AEwBTgK#v=onepage&q&f=false virtual]

Latest revision as of 03:07, 22 November 2023


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In physics and chemistry, charge is fundamentally related to fields and forces, and is a property of pieces of matter that leads to forces between spatially separate pieces of matter that likewise manifest that particular property. There are a wide variety of such charges. In the Standard Model, there are three types of charge: color, weak isospin and weak hypercharge.[1] These include the electric charge underlying electric current that enters Maxwell's equations for the electromagnetic field. In addition, there is mass that enters gravitation.[2]

These charges are conserved quantities and are related to currents describing their flux or motion. The conservation law relating the charge to its current is of the form:

where div is the vector divergence operator, J is the vector current density, and ρ is the charge density. For a volume enclosed by a surface, this equation can be expressed by the statement that any change in the charge contained inside the closed surface is due to a current of said charge either entering or exiting through that surface.

Such conservation laws are examples of Noether's theorem, which states that every symmetry of a physical theory is related to a conservation law of this kind. This theorem is closely related to Curie's principle:

The symmetry of an isolated system cannot decrease as the system evolves with time.[3]

The best known of these conservation laws are the conservation of momentum (the current is momentum density, the charge is mass density), related to translational symmetry of the laws of mechanics, conservation of angular momentum, related to the rotational symmetry of the laws of mechanics, and conservation of energy, related to the independence of the laws of mechanics from time translations. Such symmetries are intuitive for point particle mechanics, but for the physics of general fields some symmetries are quite non-intuitive.

A formal description of Noether's theorem as related to charge is that a current ja = (ja0, ja) satisfying:

which implies the conservation of the charge Q defined by:

is a natural consequence of the ja being generators of a Lie group that is a symmetry group of the physical system.[4]

Charge and exchange forces

Forces between particles are mediated by exchange of shared properties. For example, two nucleons in the same state of motion can exchange electric charge, producing an exchange force. The Yukawa theory of nuclear force posited that nucleons (protons p and neutrons n) could exchange electric charge by trading pions according to the reactions:[5]

and forces between like particles could be introduced by exchange of zero-charge pions:

These reactions do not conserve mass or energy, they are virtual reactions. One common (although not universally accepted) "explanation" why violation is permissible is that such reactions occur very rapidly, and for very short times the energy uncertainty relation allows violation of these conservation rules.

Besides electric charge, other properties can be exchanged, such as spin (Bartlett exchange), or position (Majorana exchange).

The swapping of shared properties is a symmetry operation, the exchange of identical particles, and as such is related to conserved quantities via Noether's theorem. For example, the nucleon can be thought of as a two-state particle with an isospin that is +1/2 for a neutron and −1/2 for a proton, so the change of one to the other is an isospin exchange, and symmetry of a theory under isospin exchange indicates the theory conserves isospin.[6] In a quantized version of such a theory, isospin exchange could be moderated by the pion reactions above.

Only if isospin symmetry in the theory can be produced by a continuous transformation (one depending upon some continuously variable parameter), does it lead to an isospin current conservation law.

Electrodynamics

In electrodynamics, two types of charge are known, magnetic and electric. The distinguishing property of electric charge is that electric charges can be isolated, while while an isolated magnetic charge or magnetic monopole never has been observed.[7] Electric charges interact with magnetic charges only when in relative motion one to the other.

The conservation of electric charge follows directly from Maxwell's equations. It also can be derived from Noether's theorem as a result of a gauge invariance of Maxwell's theory when that theory is expressed in terms of a vector potential. Although this approach has continuity with much of modern field theory, it is somewhat unintuitive, as the "symmetry" of the recast Maxwell equations is simply due to introduction of a mathematical device that adds an unnecessary degree of freedom into the formulation thereby introducing this symmetry artificially.[8] Below is a digression on this topic.

The basic electric field E and magnetic field B of Maxwell's equations can be replaced by introduction of a scalar potential φ and a vector potential A using the relations:
Although the potentials uniquely determine the fields, the reverse is not true. Different potentials produce the same fields; in particular the potentials denoted by primes below produce the same fields:
Here Γ = Γ(r, t) is any continuous function of the space-time coordinates r, t. Consequently, a theory based upon potentials instead of fields has the additional symmetry that it is unchanged by substitution of primed potentials instead of the original potentials. This change of potentials from unprimed to primed is called a gauge transformation and this new symmetry leads directly to the continuity equation for electric charge:
This equation is a direct consequence of the Maxwell equations defining charge and current densities (in Heaviside-Lorentz units):
However, using the potential formulation, the continuity equation is required if the theory is to be gauge invariant,[9] and this requirement is consistent with Noether's theorem.

In a quantized theory based upon the potential formulation of Maxwell's equations, the electrical force between charged particles is an exchange force mediated by trading charge-neutral photons. The electromagnetic potentials exist as vibrations with certain allowed amplitudes determined by the number of photons employed, and field amplitudes are increased or decreased by adding or subtracting photons. Thus, the force exerted upon a charged particle as determined by the field it experiences, depends upon the number of photons in the corresponding potentials.

Weak forces

Weak forces are mediated by the electric charged W+ and W particles and the electric charge neutral Z0 particle, all with spin 1. The weak interaction is of short range, being effective over a distance of approximately 10−3 fm. Analysis of the weak force parallels that of the electromagnetic force, apart from the huge mass of the exchanged particles compared to the photon. The "weak force" charge introduced that couples to this force is called flavor.[10] It is customaryu to refer to lepton flavor, rather than lepton charge, and individual lepton flavors are attributed to each family: electron flavor Le for electrons; muon flavor Lμ for muons; tau flavor Lτ for taus.[11] p. 38 However, the terminology is somewhat confused. Some authors do refer to both "weak charge" and to "lepton flavor".[12] The issue may be that quarks and leptons behave differently under the weak force?

Nuclear forces

In 1935 Yukawa invented the meson theory for explaining the forces holding atomic nucleii together, an assemblage of neutrons and protons. The theory led to the experimental observation of the pion or π-meson and the muon or μ-meson. The behavior of nuclear forces was explained as an exchange of mesons. Today, mesons are considered to be quark-antiquark pairs, and a more refined theory of nuclear interactions is based upon quantum chromodynamics. Nuclear forces are not considered fundamental today, but are a consequence of the underlying strong forces between quarks, also called chromodynamic forces or color forces. On that basis, nuclear forces are an exchange force fundamentally based upon color, and only approximated by the Yukawa theory.

Chromodynamics

In the Standard Model of particle physics, quantum chromodynamics describes the strong force, also called the color force or chromo force, and relates it to the color charge as a property of quarks and gluons.[13] Similar to magnetic charge, color is not seen directly, as all observable particles have no overall color.[14] As with electric and magnetic charge, color charge can be multiple valued, conventionally called red, green or blue. Color charge is not assigned a numerical value; however, a superposition in equal amounts of all three colors leads to a "neutral" color charge, a somewhat stretched analogy with the superposition of red, green and blue light to produce white light.[15] Thus, protons and neutrons, which consist of three quarks with all three colors are color-charge neutral. Quark combinations are held together by exchange of combinations of eight different gluons that also are color charged.[16][17][18][19]

The color charges of antiquarks are anticolors. The combination of a quark and an antiquark to form a meson, such as a pion, kaon and so forth, leads to a neutral color charge.

Other charges

The charges above are related to fields and forces and to a local (coordinate dependent) Noether's theorem. Other charges are known, however, that are connected to global or discrete symmetries (no continuous parametric dependence, such as a coordinate dependence) and so to a global Noether's theorem, and have no relation to forces or fields.

One such charge in elementary particle theory is the baryonic charge, B, also referred to as a number, with value +1 for all baryons (notably, neutrons and protons, but also others like the Λ and Σ particles) and −1 for all antibaryons and zero for non-baryons. Quarks are an exception, and have a baryon number of 1/3. Unlike electric charge, which serves as a source for the electromagnetic field, baryon charge is not related to an associated "baryonic" field.[11]

Finally, we mention the leptonic charge (also called lepton number) carried by leptons: electrons, muons, taus, and their associated neutrinos.[15] Lepton charge depends upon the flavor of the lepton[10] Le, Lμ, Lτ with values +1 for the electron, muon and tau meson, and −1 for their antiparticles.[11] The total lepton number L of a complex is:

Non-leptons have a total lepton number L of zero. Within the Standard Model, lepton number is conserved for strong and electromagnetic interactions; however, it is not necessarily conserved in weak particle reactions.[11][20]

References

  1. John F. Donoghue, Eugene Golowich, Barry R. Holstein (1994). Dynamics of the standard model. Cambridge University Press, p. 24. ISBN 0521476526. 
  2. Mark Burgess (2004). “Chapter 12: Charge and current”, Classical covariant fields. Cambridge University Press, pp. 325 ff. ISBN 0521813638. 
  3. Some care is needed in looking at this principle because of the phenomenon of spontaneous symmetry breaking. For example, as a cubic ferroelectric material like BaTiO3 is cooled below its Curie point, its cubic symmetry is replaced by a tetragonal ferroelectric symmetry as the frequency corresponding to a tetragonal elastic distortion tends to zero (Goldstone's theorem). The overall cubic symmetry of the crystal is retained because the crystal breaks into finite domains, each with a differently oriented tetragonal axis, so that statistically the symmetry of an infinite crystal still is cubic. For a general discussion, see F. Strocchi (2008). Symmetry breaking, 2nd ed. Springer. ISBN 3540735925. 
  4. Nina Byers (1994). The Life and Times of Emmy Noether: Contributions of Emmy Noether to Particle Physics. UCLA/94/TEP/42; hep-th/9411110. Presented at the International Conference on THE HISTORY OF ORIGINAL IDEAS AND BASIC DISCOVERIES IN PARTICLE PHYSICS, Erice, Italy, 29 July - 4 August 1994.
  5. Hari Jeevan Arnikar (1995). Essentials of nuclear chemistry, 4th ed. New Age International, p. 16 ff. ISBN 8122407129. 
  6. Dwight E. Neuenschwander (2010). “§9.1 Conservation of properties and unitary transformations”, Emmy Noether's Wonderful Theorem. The Johns Hopkins University Press, p. 192 ff. ISBN 0801896940. 
  7. Douglas C. Giancoli. Physics for scientists and engineers with modern physics, 4rth ed. Pearson Education, p. 708. ISBN 0132273594. 
  8. K.-H. Rehren, E Seiler (2007). Ion-Olimpiu Stamatescu, Erhard Seiler, eds: Approaches to fundamental physics: an assessment of current theoretical ideas. Springer, p. 401. ISBN 3540711155. “Gauge symmetry was originally observed within Maxwell's theory of classical electrodynamics as an ambiguity related to the artificial introduction of unobservable potentials in order to solve two of Maxwell's four equations.” 
  9. WN Cottingham, DA Greenwood (2007). “Gauge transformations”, An introduction to the Standard Model of particle physics, 2nd ed. Cambridge University Press, p. 41. ISBN 978-0-521-85249-4. 
  10. 10.0 10.1 Paul Allen Tipler (2007). “Summary table”, Physics for scientists and engineers: Elementary modern physics, Volume 3, 6th ed. Macmillan, p. 1409. ISBN 1429201347. 
  11. 11.0 11.1 11.2 11.3 O. M. Boyarkin (2007). “Chapter 3: Leptons and hadrons”, O. M. Boyarkin, Alfred L. Heinzerton, eds: Introduction to Physics of Elementary Particles. Nova Publishers, pp. 37-40. ISBN 160021200X. 
  12. Yorikiyo Nagashima, Yoichiro Nambu (2010). Elementary Particle Physics: Volume 1: Quantum Field Theory and Particles, Volume 1. Wiley-VCH, p. 554. ISBN 3527409629. 
  13. Stephen Webb (2004). Out of this world: colliding universes, branes, strings, and other wild ideas of modern physics. Springer, p. 190. ISBN 0387029303. 
  14. Andrew Watson (2004). The quantum quark. Cambridge University Press, pp. 170 ff. ISBN 0521829070. 
  15. 15.0 15.1 M. Y. Han (1999). Quarks and gluons: a century of particle charges. World Scientific, p. 116. ISBN 9810237456. 
  16. Joe Rosen (2004). Encyclopedia of physics. Infobase Publishing, p. 85. ISBN 0816049742. 
  17. Joe Rosen, Lisa Quinn Gothard (2009). Encyclopedia of Physical Science, Volume 1. Infobase Publishing, p. 278. ISBN 0816070113. 
  18. (2009) “Quantum chromodynamics (QCD)”, Daniel M. Greenberger, Klaus Hentschel, Friedel Weinert: Compendium of Quantum Physics: Concepts, Experiments, History and Philosophy. Springer, pp. 524 ff. ISBN 3540706224. 
  19. OW Greenberg (2008). "The color charge degree of freedom in particle physics". Chapter in Greenberger et al. below.
  20. Helen R. Quinn, Yossi Nir (2010). “Chapter 12: Baryon and Lepton number conservation?”, The Mystery of the Missing Antimatter. Princeton University Press, p. 130. ISBN 1400835712. 

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