Talk:Dielectric

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Surely the E-field is directed from the positive charge to the negative one? The article states that "Note that the dipole moment is shown to be pointing in the same direction as the electric field.", which means that the dipole moment is also directed the wrong way around (it points from - to +)!--193.157.137.193 (talk) 19:39, 14 June 2012 (UTC)[reply]

See electric dipole moment for direction. Materialscientist (talk) 22:37, 14 June 2012 (UTC)[reply]

In the section on Paraelectricity, there is still a strange statement that for this "normal class" of materials, the polarization (= density of electric dipoles) aligns opposite to the electric field. Must be a similar sign error: I removed the parenthesis "(and opposite)".DieHenkels (talk) 09:59, 1 November 2021 (UTC)[reply]

Similar problem with "permittivity tensor being a diagonal tensor": that is not sufficient for having a polarization parallel to the field, since one may have different numbers on the diagonal. I changed to "proportional to the unit tensor".DieHenkels (talk) 09:59, 1 November 2021 (UTC)[reply]

In a dry transformer, is air the dielectric medium? As I understand it, a dieletric acts as a bad conductor of electric current but conducts magnetic fields well.

A "dry transformer" is simply a transformer that contains no oil. Various other dielectric materials are used instead - these may include electrical varnish or epoxy resins in addition to paper, enamel wire insulation, etc. During transformer manufacture, fluid varnish or epoxy is often forced into the transformer (called vacuum impregnation), and is then hardened in place by baking. This process is used to remove small air gaps near the windings in order to prevent corona formation particularly in higher voltage/power transformers. However, these suplemental dielectrics play no part in helping to conduct magnetic flux since their relative permeability is usually about 1 (similar to that of air). Bert 22:56, 11 April 2007 (UTC)[reply]

Hi, I've deleted nothing, but added an overview called "Beginner's Corner." The idea is to draw a wider readership into the article. The ploy is reaching for relationships to observations or knowledge the not-so-technical reader already has. We're not dumbing down here, we're reaching out. Hopefully some new readers will want additional rigor and find it right here in the more "Wiki classic" parts of the article. I can be aroused from slumber at jerry-va at speakeasy dot net. Jerry-VA 01:46, 7 September 2006 (UTC)jerry-VA[reply]

Thanks very much Jerry, I came upon this article by googling some links and if I hadn't gone to the talk session and un-earthed your contribution, I would have clicked away very quickly. I know there are people that are mathematically inclined by nature (I generally count myself among them), but it would be nice if there was some establishment of the basics without getting too technical.

I came specifically looking to know 'what is a dialectric constant and what do the numbers mean? If water's DC is 80 and DMSO's DC is 36 which one would be better/worse for use as a dialectric material? I read the entire page and although the first is answered extensively, I don't see

a) a single example of a few common elements with their numbers b) whether a "higher" constant is a higher or lower number c) whether a "higher" constant means greater insulation or greater polarized capacitance (If I said that wrong, remember I'm new or I wouldn't have been reading it for info to begin with. But something real simple like, "If you wanted a dialectric material to improve the transmission of radio waves, X (##) would be better than Y (##)." That would have told me immediately everything I needed to know in B and C above.) I appreciate the efforts authors have made to create and maintain this page. It would be very helpful if the three points above could be added, perhaps to the beginner's corner. Palyne (talk) 16:52, 7 August 2013 (UTC) Palyne 07Aug2013[reply]

I'm a beginner too. Higher numbers means they are better dielectric materials [see: https://en.wikipedia.org/wiki/Relative_permittivity ] 129.78.233.210 (talk) 01:02, 7 April 2015 (UTC)[reply]

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how does dielectric constant vary with temperature?

Depends on the material. How long is a piece of string.--Light current 03:16, 27 January 2006 (UTC)[reply]

How long is a piece of string.-No. More like "what is the color of metal?" The answer to your question is that different materials have different dielectric constants. The permittivity(dielectric constant) originates from a materials being polarizable(sp?) in an electric field. If the field is varying with time then how in tune(or in phase) that polarization is determines its imaginary part. In general, one cannot assume the dielectric constant is independent on temperature, electric field, or magnetic field. One reason being is that these parameters can apply forces on an atomic scale that can change the how far apart the atoms are, which has a role in determining the permittivity. --TheDeuce1123 05:16 6/29/07

If the presence of a dielectric (E >1) can distort an electric field, does the presence of a ferromagnetic material (U>1) distort a magnetic field from a magnet. If so, what do iron filings do to the magnetic field when spread around a bar magnet? 8-?--Light current 00:12, 4 May 2006 (UTC)[reply]

generally speaking, different manifestations of the same force. 98.246.108.1 (talk) 09:09, 31 December 2008 (UTC)bk[reply]

I have made a correction to the definition of a dielectric in the introduction. Also, I excised this paragraph which is both poorly-phrased technically and somewhat misleading.

Electrically, the dielectric constant is a measure of the extent to which a substance concentrates the electrostatic lines of flux. More specifically it is the ratio of the amount of electrical energy stored in an insulator, when a static electric field is imposed across it, relative to vacuum (which has a dielectric constant of 1). Thus, the dielectric constant is also known as the static permittivity.

Yeah I noticed. I put it back. Rewrite if you wish, but lets keep the info 8-)--Light current 19:55, 28 July 2006 (UTC)[reply]

Can somebody explain what this means:

The presence of a dielectric concentrates the applied electric field (e-field) within itself.

Can you please sign and date your posts by typing ~~~~ . THanks. THen we can talk--Light current 12:32, 29 July 2006 (UTC)[reply]

Well, the article's wording probably could be changed to be a bit clearer. When a dielectric with a relatively high dielectric constant (k) is immersed within a uniform electrical field (i.e., within free space or within another dielectric having a lower dielectric constant), the shape of the E-field near the dielectric becomes distorted. In the case of a dielectric sphere or cylinder, the nearby E-field lines are "attracted" to, and concentrated within, the dielectric material. Similarly, if the sphere has a lower dielectric constant than its environment (i.e., an air bubble in oil), the E-field will tend to avoid the sphere, preferring instead to flow around it. Discussions, including images showing the effect on E-field lines for higher and lower k spheres and cylinders can be seen at [1] and [2]. A more general discussion, including a description of a conductive sphere in a uniform field (E-field always normal to the surface), can be found at [3] Bert 14:28, 29 July 2006 (UTC)[reply]

Trying to remember 2nd year EM. If I am right about what a dielectric really is then its best to introduce the mathematical model first. Then it becomes apparant why the term a "good" dielectric can be ambiguous. The modle assumes that for a basic element (atom) there is a mobile charge cloud (electrons) surrounding an oppositely charged point charge (nucleus). A force (electric field) distorts the charge cloud inducing a dipole. The key is that the force (electric field) is proportional to the dipole. NB we are usual talking in vectors so it points in the same direction as well. This is the model of SHM, a favorite in physics because it is usually first order accurate. This means it gets close to the answer in normal circumstances, plus it is linear i.e. easy. Please forgive the language I am just being perdantic that the model doesnt require the objects to be anything specific but almost 100% of the time we are talking about atoms and electric fields. Plus the electric field can be from something like a capaciter or something like light. The model can be used to describe many different phenomina is solid state physics, and often physitsts in different fields call the same object by a different name.

When talking about a "good" dielectric the ambiguity comes whether you mean the substance obeys the model or not OR the substance does obey the model and the constant of Proportionality (mathematics) is large often called the dielectric constant, but I am sure it goes by many names depending of the field of physics you are talking about. For instance glass does obey the dielectric model very well but the dielectric constant is small. Metals can be said to be poor dielectrics because the model doesnt work. Anything that conducts well cannot be a dielectric! I hope 1. this makes sense, 2. is right and I am not getting confused with something similar.

Things start to get interesting when the dieletric constant chages on position of the basic element, called inhomogenety, the opposite of homogeneity (physics), or if the the dielectric constant changed depending on the direction of the electric field called anisotopy. Contact me if you want to improve this article because I think we can all agree the article is in a poor state.

Timwilson85 18:31, 19 September 2007 (UTC)[reply]

I just found the definition segment of this flawed because it explains a lot about how to think about atoms and electric fields in all sorts of matter, but it doesn't give me the slightest hint of how to apply the term "dielectric" to a material; in other words, if I say this substance is a dielectric solid, what am I saying about it? How is it distinguished from a substance that is not a dielectric solid? Because the article later goes on to describe some properties of dielectric solids and gases, the ability to distinguish between dielectrics and non-dielectrics is crucial.--Slothropslothrop (talk) 23:24, 16 December 2007 (UTC)[reply]

I asked my professor what a dielectric material is, and he said it is a nonmagnetic material. Something should be not be defined by its uses, but instead by what distinguishes it from everything else. That is to say, not all dielectric materials are used in capacitors, so they should not be defined that way. Zylorian (talk) 22:28, 15 January 2010 (UTC)[reply]

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I added an external link on dielectric properties of polymers. I had this there before but in html so it had some marketing-ese in it and it got deleted. I found the .pdf so now it is all technical. I know it would be great to include some of the ideas and then just link but I can't do that (not enough experience in this area.) Hope this is OK Rsteif 15:48, 13 December 2006 (UTC)[reply]

"also called the static permittivity or dielectric constant ε_s"

Does anybody else realize that this is whack? Click the link for dielectric constant, and you'll be linked to an article that includes a phrase "also known as relative permittivity". So... by somebody's logic... static permittivity = relative permittivity. Sweet.

Also, if there is some technicality here that I'm not understanding, perhaps there needs to be some sort of disambiguation going on that might clarify the relationship between these two quantities.

69.156.153.12 01:08, 28 February 2007 (UTC)[reply]

I read a little more, and I realized that the Dielectric Constant article is referring to a "relative dielectric constant"... perhaps that needs to be disambiguated.

The permittivity(or dielectric constant) of most materials is dependent on frequency, but it is not a separate unrelated quantity when it is in a static electric field it is simply that same quantity with freq=0Hz.TheDeuce1123 05:47, 29 Jan 2007

I have proposed this article should be merged one way or the other with electrical insulation. The two terms are essentially synonyms. Oli Filth 16:42, 17 June 2007 (UTC)[reply]

Agree, Dielectric should become a sub-section of the Electrical Insulation page.(A. Carty 19:06, 18 June 2007 (UTC))[reply]

That's OK providing that anyone looking for a definition of dielectric gets pointed to the correct place. Pete Male

I think there should just be permittivity. The problem is what are you talking about: a dielectric constant? a material used to insulate a transmission line? Whatever you are talking about you it all goes back to permittivity. I do not think Dielectric should be merged into electrical insulator, that is wrong. A dielectric does not simply mean or refer to electric insulator.

Thats my opinion though.

I believe we should distinguish between two important contexts: electrical phenomena and optical phenomena. From a theoretical point of view it comes to the same thing, but don't forget that people are specialized in different fields, and don't necessarily underspend the whole physics behind this concept. In the spirit of Wikipedia, which is to bring free quality information to everyone on the planet, I propose to maintain the distinction mentioned above. (TiberiusB)

A good dielectric is a good insulator but the reverse is by no means true (ex. polymer). They share similarities but are fundamentaly different. The two articles should not be merged.

I disagree on merging the topics, dielectric should remain separate but needs a better general introductory paragraph at the 5-8th grade level that links the different fields (RF, Capacitors, Insulators, Antennas, Permitivity, etc.) DjK64.56.105.162 15:33, 23 July 2007 (UTC)[reply]

I also disagree - though they touch on similar characteristics, they're discrete enough topics that merging the two could cause information overload. Simpler to comprehend in this format. Agree that dielectric as a topic needs to be fleshed out, though. Anon. 12.10.219.38 22:22, 7 August 2007 (UTC)[reply]

I also disagree. The subjects are related but sufficiently dissimilar to justify two separate artilces.

I strongly disagree. The dielectric page needs contain much more technical detail on what a dielectric is, underlying assumptions. Why these aproximations are made ie. simplification to maxwell's equations etc Timwilson85 17:28, 16 August 2007 (UTC)[reply]

I strongly disagree. I came here looking for information relevant to dielectric material use in microwave engineering, and would be poorly served if I had to page through insulation (which in this case has next to nothing to do with the properties of dielectric materials). 98.246.108.1 (talk) 09:07, 31 December 2008 (UTC)bk[reply]

I am starting to completley re-write this article if anyone wishs to help, even if it is just to check what I write make sense just leave your user name underneath and I will contact you when I make a change. People checking my SPAG (Spelling, punctuation and grammer) most welcome :-) Timwilson85 17:31, 21 September 2007 (UTC)[reply]

Added the basic definition of dielectric. Next addition will be some mathsy stuff to do with dielectric constast, permitivity, suseptability. Timwilson85 12:35, 22 September 2007 (UTC)[reply]

Added a bit onto the defintion introducing some of the phenomina to be explained. Also started the special case of free space. I am havibng trouble deciding on the correct order in which introduce topics. My background is optics so the article may be a bit skewed towards opticla effects. Timwilson85 22:59, 24 September 2007 (UTC)[reply]

Someone needs to deal with the moron who inserted 'citation needed' in the description of basic atomic theory. 98.246.108.1 (talk) 09:08, 31 December 2008 (UTC) bk[reply]

4th section: '... permitivity of free space' -- that should be 'permittivity —Preceding unsigned comment added by 209.113.244.86 (talk • contribs) 16:32, 4 January 2008

--"So fix it dear Liza, dear Liza. So fix it dear Liza, fix it." Get with the wiki program and make the change yourself. That is the whole point. You are empowered to make the change yourself. Isn't it grand? By the way, I went ahead and fixed it for you. --158.35.225.228 (talk) 14:16, 15 May 2008 (UTC) (Just like the previous sentence used to have some typos, but now they're fixed)[reply]

Can somebody please add a paragraph about this aspect of dielectrics?--83.105.33.91 (talk) 13:36, 2 August 2008 (UTC)[reply]

"Whewell considered "dia-electric", from the Greek "dia" meaning "opposed in moment", since an electric field passes through the material but felt that "dielectric" was easier to pronounce." - I don't think that "through" is a very sensible translation of the "dia-" prefix in this context. I'm fairly certain that an electric field doesn't pass through an insulator. Also, not that I agree with, but, a couple dictionaries cite the etymology of "dielectric" as "di- + electric" rather than "dia- + electric". Fuzzform (talk) 22:54, 8 October 2008 (UTC)[reply]

The greek prefix di- means "twice", "double". The greek prefix dia- means "through" and loses the "a" before a vowel, thus dia- + electric (δια + ηλεκτρικός) -> dielectric (διηλεκτρικός). From http://hermital.org/book/holoprt5-1.htm (note 8 - Letter 1798, William Whewell to Faraday, p. 442): "As to the name for the antithetical classes of bodies, I consider thus. I suppose you called one class dimagnetic from analogy with dielectric. I think you ought to have said diamagnetic; for the bodies through (dia) which electricity goes would have been called diaelectric, but that vowels in such cases coalesce. I think you may keep diamagnetic for this class, and give to the opposite class a name implying that they rank along with magnetic bodies. I propose paramagnetic. (Whewell's emphasis)" Episcophagus (talk) 08:57, 30 May 2011 (UTC)[reply]

This article is largley unsourced. Please add reference Bastien.roucaries (talk) 14:18, 18 December 2009 (UTC)[reply]

Shouldn't this article mainly contain standard material, covered in lots of textbooks ? I agree that this article needs work, but I don't think references ought to be a major concern. -- Marie Poise (talk) 18:41, 18 December 2009 (UTC)[reply]

What do you think about creating a new article about dielectric relaxation ? Bastien.roucaries (talk) 14:19, 18 December 2009 (UTC)[reply]

Definitely a good idea. I look forward to your edits. -- Marie Poise (talk) 18:39, 18 December 2009 (UTC)[reply]

The first sentence in this article says,

 A dielectric is an electrical insulator that can be polarized by an applied electric field.

This phrasing suggests that there are electrical insulators that are not dielectrics: i.e., that there are electrical insulators which *cannot* be polarized by application of an electric field. The article has examples of materials that are dialectrics, but I think it would benefit from some examples of materials that are not dielectrics. Draconx (talk) 23:22, 14 November 2012 (UTC)[reply]

Dielectric relaxation is described as a "delay (or lag) in the dielectric constant". Does this make sense? Is the dielectric constant changing, or is it the polarization? Is relaxation a delay, or it rather a process that causes a delay? I would write, if it is scientifically correct:

Dielectric relaxation is the process whereby dipole charges move to their polarized (or less polarized) positions in response to a changing electric field in a dielectric medium (e.g., inside capacitors or between two large conducting surfaces). This does not occur instantaneously, but causes a momentary delay (or lag) in the adjustment of the polarization to match the electric field. This delay is called the dielectric relaxation time.

I don't know what to do about the reference to "molecular polarization". Does this mean that the concept of dielectric relaxation is generally only applied (or relevant) to molecular (distortion) polarization, as opposed to other polarization effects that are mentioned earlier in the article, such as dipolar polarization, ionic polarization and electronic polarization, with their very different cutoff frequencies?

In the second paragraph, dielectric relaxation is defined as a form of relaxation that occurs at microwave frequencies. From earlier in the article, this is the frequency cutoff for dipolar polarization, not molecular polarization. Why has the relevant frequency range changed? Is dielectric relaxation now a different phenomenon at a new typical frequency?

Hemming's law seems to be out of place -- it introduces a highly specific formula, but without really explaining the underlying phenomenon.

I didn't make any changes because I don't know the science at an expert level. 84.227.226.188 (talk) 16:53, 11 April 2014 (UTC)[reply]

I don't understand the sentence "Ionic polarization causes the ferroelectric effect as well as dipolar polarization". How are ionic polarization and dipolar polarization related? I though the mechanism were different. 84.227.226.188 (talk) 08:24, 12 April 2014 (UTC)[reply]

How does the phenomenon described in the section entitled "paraelectricity" differ from the linear polarization response ${\displaystyle {\mathbf {P} }=\varepsilon _{0}\chi _{\text{e}}{\mathbf {E} }}$ that one expects to see in many dielectrics? It is described in many articles. If so, shouldn't the connection be made that this is really the same phenomenon? 84.227.226.188 (talk) 08:40, 12 April 2014 (UTC)[reply]

In Ferroelectricity#Polarization it states that paraelectric means a certain kind of nonlinearity. I couldn't remotely get this from the section in the current article. I made a link, at least. 84.227.226.188 (talk) 18:47, 12 April 2014 (UTC)[reply]

This section is way too technical! It leaps out from the page!! I understand the achievement described is worthy but still, this level of specificity shouldn't be here.

Also, what does the definition mean: "Tunable dielectrics are insulators whose ability to store electrical charge changes when a voltage is applied" ? Is it the susceptibility (and hence the capacitance, i.e. ability to store charge per electric field strength) that changes? In this case, it's just the same as saying that the response of polarization P to electric field E is nonlinear. But surely something more specific than that is being claimed. Engineering usefulness comes from specific shapes of nonlinearity, not just linearity in general. 84.227.226.188 (talk) 08:54, 12 April 2014 (UTC)[reply]

To the main editors: I wonder if the following sentence, the 3rd in the 1st paragraph of the article, "Because of dielectric polarization, positive charges are displaced TOWARD THE FIELD and..." is complete enough. Should not it said "toward the NEGATIVE SIDE of the field...", or something like that? Even if the sentence is correct and clearly understandable for people with knowledge, could it be modified for clarification and fixing any doubt in people lacking that knowledge? Thank you for considering the request. Pmronchi (talk) 14:36, 24 March 2015 (UTC)[reply]

"While the term insulator implies low electrical conduction, dielectric typically means materials with a high polarizability. The latter is expressed by a number called the relative permittivity"

Can you give examples of good dielectrics and poor dielectrics? Like copper is a good thermal conductor and electrical conductor, while diamond is a good thermal conductor but a poor electrical conductor. Similarly are there materials that are good insulators/good dielectrics, and other materials that are good insulators/poor dielectrics?

The first paragraph says "for example, if the field is moving in the positive x-axis, the negative charges will shift in the negative x-axis" (emphasis mine). I am not schooled in this subject, but is this perhaps a misstatement of "for example, if the field is oriented in the positive x-axis, the negative charges will shift in the negative x-axis"? Meaning, the field in that example isn't "moving", the author only meant to emphasize the direction of the field lines? Given the importance of moving/changing electric fields and the frequency with which they are discussed, this language is confusing. I would change it myself but I'm not qualified to make the determination. Chconnor (talk) 21:23, 11 May 2020 (UTC)[reply]

The "Tyvek" page links to the "Dielectric" page for "dielectric bonding" but there is nothing about it here.

(Tyvek: Section: Scientific characteristics and properties - Adhesion and bonding - "Dielectric bonding can be effective in some circumstances ...")

Please would someone knowledgeable add this information ? Darkman101 (talk) 14:03, 7 June 2021 (UTC)[reply]