Talk:Electrode

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I would like to add an outbound link to two great guides and resources that deal with the proper preparation and selection of material on tungsten electrodes. The link is at: www.diamondground.com/downloads.html. Do you feel that this would be appropriate?

Hi Michael: The fact that physicists and chemists use opposite conventions for cathode and anode is the cause of much confusion between the two groups. I believe electrical engineers follow the physics convention. This is worth noting up-front, and worth tracing its origin. One must always specify whether positive current is flowing internal or external to the galvanic cell. Chemists never think twice about this, taking internal current (following Faraday). Neither do physicists, taking external current (following, I suppose, people like Thomson). No wonder there is much confusion. The chemists have it right. Physicists are ignorant of the origins of the terminology in Faraday's studies of decomposing electrolytes. The article should address this upfront with a statement like "The terminology for cathode and anode (as well as electrode, electrolyte, cation, and anion) was given by Faraday in his studies of decomposition of electrolytes, where he was concerned with current flow through the galvanic cell. Physicists studying processes within cathode ray tubes (vacuum tubes) are interested in current flow that is external to their voltage source, and this seems to have led to a reversal in the definition of cathode and anode..." (If I have it wrong, please spell it out for me.) 165.91.181.78 15:56, 14 June 2007 (UTC)[reply]

Hi (insert your name here), which opposite conventions are you referring to!? Physicists and chemists agree that anode is where current flows in, and cathode is where current flows out, have a closer look at the chemistry and physics examples given at the top of the article you'll see they all illustrate the same definition. Regarding your internal current vs external current point, it is not a source of confusion in the present definitions in fact, for example when Wikipedia says the anode is the terminal where current flows in, it means unambiguously that it flows from the external part of the circuit into the device. It flows in whether you consider external current or internal current. Do let me know if something still bothers you. MichelJullian 22:28, 14 June 2007 (UTC)[reply]

OK. Here's what is bothering me. For a (Daniell) galvanic cell with Zn/Cu, using Faraday's definition the Zn electrode is called the anode (according to Faraday it should attract anions, but instead it "ejects" Zn++ cations, like a good sacrificial anode should) and the Cu electrode is called the cathode (it attracts Cu++ cations). The internal current flows left to right (anode to cathode) and the external current flows right to left (cathode to anode), with the electrons in the external path flowing from left to right. By Ohm's Law applied to the external wire, the electrode on the right -- that is, the cathode (in Faraday's nomenclature) -- is at the higher electrical potential. Now put 50 Daniell cells in series, to drive a (cold) cathode ray tube (imagine a small gap in the external wire). Electrons will jump the gap and flow from left to right (as for a single Daniell cell). Here is my point. In the language of physicists, the electrode the electrons flow from is called the cathode. To me that is NOT the name of the electrode according to Faraday.

Just to make the point more explicitly, let me discuss the 3rd edition (1958) of Page and Adams' "Principles of Electricity". On p. 259 is a picture of what they call a discharge tube, and on its right is the NEGATIVELY charged "cathode". Curiously, and uncharacteristically for a physics text, on pp.170-184 they also discuss electrolysis. They do not define cathode and anode, but they seem to employ chemical usage for these terms, with metal plating onto the cathode. So it seems to me they are, unknowingly, schizophrenic, using one set of definitions in the chemical case and another set of definitions in the cathode ray tube case. If physicists and chemists have different definitions, then it is worthwhile to point this out and, if possible, suggest how that could have come about. 74.192.217.168 04:13, 15 June 2007 (UTC)[reply]

You have it all right, except your conclusion that physicists and chemists have different definitions. In the galvanic cell, as you say, the internal current flows from anode to cathode. In the discharge tube, as you say, electrons flow internally from cathode to anode, i.e. internal current flows from anode to cathode. It's the same. The only difference is polarity, cathode being the positive (highest potential) terminal in the galvanic cell whereas it is the negative terminal in the discharge tube, but anode and cathode definitions are NOT polarity based as is commonly and mistakenly believed, they are current direction based. Besides the "cathode = negative terminal" case is not physics specific, it's the same in electrolytic cells, for which the terms were initially invented. In fact it's the same in all passive devices, as without a source of energy (chemical in the case of the galvanic cell) there is no way you can make internal current run from the lowest to the highest potential. Let me know if the controversy is solved. MichelJullian 06:36, 15 June 2007 (UTC)[reply]

BTW, I realized that the "anode and cathode are of fixed polarity" common misconception mentioned above, although discussed at length in this talk page, was not even mentioned in the articles themselves where it would be more useful. I corrected this omission in the illustrating examples paragraph. MichelJullian 13:36, 15 June 2007 (UTC)[reply]

The Wikipedia entry on cathode ray indicates that in 1838 Faraday himself studied luminescence in (partially) evacuated glass tubes. It is doubtful that he saw rays, because he had a poor vacuum, and could only see luminescence. I will assume that he called the negative electrode, into which current flows, the cathode (but I really would like to read his notebooks on this). Then, when better vacuums were obtained, cathode rays would have been seen. I'm not happy with the convention, but if Faraday used it for both the interior and exterior of a galvanic cell, I'd better not question it. So I should not be asking when did physicists confuse the interior and exterior of a galvanic cell?, but rather when did physicists start thinking that cathode and anode are voltage-defined? That would likely have been in the 1890's, when physicists lost interest in electrochemical cells and developed an interest in cathode rays and electrons and, eventually, other particles. Thus, assuming that I understand the naming convention, I would be satisfied with definitions of cathode and anode that read something like this:

"The definitions of cathode and anode are current-based, not voltage-based, and depend upon the path along which the current flows. To determine which of two electrodes A and B is the cathode or anode: (1) choose the path between them (which for a Zn/Cu Daniell cell could be either a path through the electrolyte of the interior or through an exterior wire connecting its two electrodes); (2) for this path, define the anode as the electrode from which the current leaves, and the cathode as the electrode into which the current enters. Being path-dependent, the definitions of of cathode and anode for a single loop circuit switch if, rather than choose the interior path, you choose the exterior path. With a Daniell cell, for a path through the cell the Zn electrode is the anode; but for a path through an exterior connecting wire, the Zn electrode is the cathode." At some later point one could note: "For the external connecting wire, electrons leave the cathode to go along the wire to the anode, and this would continue to be true if the wire had a small spark gap through which the electrons passed, thus simulating a cathode ray tube, where the electrons pass from the cathode to the anode." This is still too wordy.

Faraday, in his original article, also talked about "poles", which may have been the other end of his electrodes. It is worth figuring out, but I can't do that at the moment. Sandman42 165.91.181.78 17:06, 15 June 2007 (UTC)[reply]

Hi Sandman, I didn't follow all the intricacies of your example but in the end you're right, the Zn electrode would be both the galvanic cell's anode and the spark gap's cathode. I am tempted to say "and so what?", this does not contradict the present Wikipedia definitions (ACE and CCD in short), which are openly device-based ("enters" or "departs" refers to the device you are considering obviously), no need to specify a path. I still see no disagreement between chemists and physicists. The misconception that electrodes are polarity-defined is not physicist specific either, some chemists exclusively concerned with electrolysis also believe that "the anode is the positive electrode", so they are only right as far as their trade is concerned. Do let me know if anything still bothers you.

Your understanding of Faraday's poles is basically correct, at the time he made a distinction between the electrical terminal itself (the pole) and the surface separating the pole from the electrolyte (the electrode = the current doorway). This nuance has been lost since, as explained in the excellent Ross paper. MichelJullian 22:19, 15 June 2007 (UTC)[reply]

What bothers me is that, with this definition, anode and cathode are relative, not absolute, definitions. I think this should be stated up front, as a warning to the reader. Consider a ring centered on the origin, and a point A on the ring at 0 degrees and a point B at 180 degrees. If a bead on the ring moves counterclockwise, then for the bead in the upper quadrants we might say that "start" was at A and "end" will be at B, but for the bead in the lower quadrants we might say that "start" was at B and "end" will be at A. There is method behind the madness, but I find it bothersome that the definition is relative. On the other hand, if a circuit has multiple arms, in some of which there are galvanic cells, then perhaps we can only speak about one arm at a time. Yeah, maybe that's the ticket... However, until physicists (some chemists too, evidently) dig deeply, it will be difficult to unlearn the voltage-based definition. Clearly, I have had that difficulty. I have talked to at least a few other physicists, and they too have been confused on this matter. Mostly, the problem is that it is difficult to unlearn something. Sandman42WMSwiki 23:39, 15 June 2007 (UTC)[reply]

Looking at the articles for electrode, cathode, and anode, I note from the figures presented that only for the first would it be possible to state that the definition is absolute. For the cathode and anode the figures are for Cu and Zn in a Daniell cell. That would imply that the definition is absolute, which we agree it is not. So there is a problem with these articles. Sandman42 WMSwiki 23:44, 15 June 2007 (UTC)[reply]

Misprint above! Missing NOT. Replace the above paragraph by:

Looking at the articles for electrode, cathode, and anode, I note from the figures presented that only for the first would it be possible to state that the definition is NOT absolute. For the cathode and anode the figures are for Cu and Zn in a Daniell cell. That would imply that the definition is absolute, which we agree it is not. So there is a problem with these articles. Sandman42 74.192.217.168 02:30, 16 June 2007 (UTC)[reply]

I agree it's difficult to unlearn the voltage polarity based definition, I found it difficult myself as recently as last year. The root of the confusion in my case, and others I know, was that since positive cations go to the cathode I concluded erroneously that the cathode must necessarily be negative :-) Indeed the anode and cathode figures only show one example so they lack generality. But it's an interesting one, in that it contradicts the "anode is positive and cathode is negative" most common misconception, and it shows positive ions moving away from the negative electrode and towards the positive electrode (under chemical power). What do you suggest to improve generality, more figures showing other examples maybe, e.g. with the other polarity such as a diode drawing? MichelJullian 07:07, 16 June 2007 (UTC)[reply]

Oh I see what you meant by absolute I had missed your point, you mean showing the particular electrode in isolation is meaningless wrt voltages and currents. Note the caption right underneath each figure links to the full galvanic cell device with both electrodes , so there can be no confusion I would have thought. MichelJullian 08:09, 16 June 2007 (UTC)[reply]

Someone please fix cathode &/or anode: Both state electrode through which (positive) electric current flows. Thanks

No fix needed, positive current flows through both indeed but not in the same direction: through the anode it flows in (anode current enters), and through the cathode it flows out (cathode current departs). MichelJullian 08:34, 4 July 2007 (UTC)[reply]

This is a continuation of the above "do physicists..." section.

The present Wikipedia definition of cathode is "A cathode is an electrode through which (positive) electric current flows out of a polarized electrical device. Mnemonic: CCD (Cathode Current Departs)." I don't like this definition for many reasons, but here are two. (1) Why does the device have to be polarized? In a cathode ray tube the medium is a vacuum, which isn't really polarized. What is meant by "polarized"? I can't read minds. Moreover, it stops the reader. (2) I don't necessarily dislike mnemonics, but if one is inventing them, the reader should be warned. I call up the phrase "sacrificial anode" to remind me of which is which.

I do not have a good suggestion for a short, snappy definition of cathode or anode. At the very least the figures should show the full Daniell cell, and the text should make it clear that the definition is not absolute, giving an example with the Daniell cell and a connecting wire. I'll try again at a reasonable definition.

"The definitions of cathode and anode are current-based, not voltage-based. Because these definitions depend on the path of current flow, they are relative rather than absolute. Consider the accompanying figure of a Daniell cell. Chemists and electrochemists tend to be interested in the interior of the cell, where the current enters the electrolyte from the Zn electrode (for this interior path called the anode) and leaves by the Cu electrode (for this interior path called the cathode). Physicists and electrical engineers tend to be interested in the exterior of the cell, where the current enters an external wire from the Cu electrode (for this exterior path called the anode) and leaves through the Zn electrode (for this exterior path called the cathode). From the cell perspective the cathode is positive and the anode is negative. From the wire perspective the cathode is negative and the anode is positive. From both perspectives the Cu is positive and the Zn is negative. When communicating with others about "cathode" and "anode" it is important to state whether one is considering the viewpoint of an active device (the galvanic cell) or a passive device (the wire)."

Related to this, note that physicists use the convention I=(V2-V1)/R for a resistor (so current flows from high V to low V), but I=[E-(V2-V1)]/r for a battery (so current flows from the low V terminal to the high V terminal). In the limit of emf E=0, the sign convention for a zero emf battery (which still has a resistance) is opposite that for a resistor. That's wacko, but physicists live with it because then the terminal voltage is E when there is no current flow.

Sandman42 74.192.217.168 18:27, 16 June 2007 (UTC)[reply]

1) polarized = polarity matters, e.g. a resistor or a wire is not polarized, a battery or a diode or a CRT is polarized. The device has to be polarized because it wouldn't make sense to talk about a resistor's or a wire's anode.

2) mnemonics aren't generally attributed, have you ever seen it mentioned anywhere who authored the well known LEO "Loss of Electrons = Oxidation" mnemonic? As long as what the mnemonic says translates accurately the definition without harming its universality (which is not the case of your "sacrificial anode" suggestion, as there is nothing sacrificial about e.g. a CRT's anode), making up a mnemonic is no more an original creation than any particular arrangement of words making up a sentence in the article. Cf "mnemonics" section in this page for more on this. Needless to say I will be quite happy if someone comes up with better mnemonics than the present ones, or any better wording for the definition for that matter.

3) the fact that definition is current direction based rather than voltage polarity (+ or -) based is already quite explicit.

4) I submit the non-absoluteness of the defs doesn't deserve more mention _in the definitions themselves_ than saying that the definition is relative to a device, which is perfectly clear already: "...an electrode through which (positive) electric current flows out of a polarized electrical device". Many properties or definitions are similarly not absolute BTW, e.g. the "+" pole of a battery can be the "-" pole of another when they are connected in series, you will certainly agree that this goes without saying.

5) About your point that current flows "downhill" wrt potential, it's not at all a matter of physicists specific convention as you seem to suggest, it is true, but only for resistive devices, not when some source of power pushes current uphill as discussed in the GC example below each definition. Again, no disagreement between physicists and chemists.

Let me know if the definitions and examples make more sense to you in the light of the above arguments. About the drawings, replacing the partial view of the GC by a full view would be a good thing indeed, provided you find a way to highlight clearly the electrode under focus in each article (e.g. by graying the rest of the image?). MichelJullian 10:09, 17 June 2007 (UTC)[reply]

(1) Thanks for explaining this. But I don't see how the cathode and anode in a cathode ray tube are polarized, especially for what is called a cold cathode, so that both electrodes are at the same temperature. The voltage can be reversed and then one can have anode rays (positive ions), something that actually was studied in the 19th century. If polarization is needed, then my earlier discussion of a wire external to a Daniell cell, with which I thought you had agreed, was inapplicable, because (as I understand things now) the definitions of cathode and anode don't apply to things like wires. I'm still puzzled. As far as I can tell, both wires and cathode ray tubes are unpolarized. Anyway, I think you are telling me that for a wire as an external connection I should consider the Zn as the anode, just as for the Daniell cell. Please correct me if I am wrong. (The hardest thing is to unlearn something.)

(2) As mnemonics go, CCD isn't bad (but also CCD=Charge-Coupled Device).

(3) I agree that current vs voltage is already explicit.

(4) Now that I appreciate that the definition is restricted to polarized devices I am less bothered. But the issue of the Daniell cell connected by a wire or spark gap (=cathode ray tube) in the exterior arm puzzles me. For the wire do I continue to think of the Zn as the anode and the Cu the cathode, but for the spark gap (=cathode ray tube)) I reverse them? I'm not trying to give you a hard time; I really don't know. All of the general definitions puzzle me, in the absence of examples.

(5) When I invoked current flowing downhill (relative to voltage), the context was Ohm's Law, which applies only to passive devices like resistors.

(6) About the drawings: one could just leave the full GC, but give more information in the caption and in the text. I am a strong believer in redundancy. Some people try to get their information from the figures alone; some use the figures as entries to the article; some read the article and refer to the figures only when appropriate. Sandman42 74.192.217.168 17:58, 17 June 2007 (UTC)[reply]

(1) and (4) the ART obtained by polarizing your CRT in reverse has a different current-voltage characteristic, especially if the vacuum is such that there is not enough gas inside to make anode rays with, in which case your device is effectively a diode ---the archetype of a polarized device. I see we are interested in the same things (everything basically), but let's not digress too much, our discussion has already doubled the length of this already initially lengthy talk page :) When we say polarization is needed, well I suppose you could talk about your wire's anode if you really wanted to ---in which case in your example I maintain it wouldn't be the Zn but the Cu, because that's where current enters the device (the wire in this case!), ACE "anode current enters", remember? ;-) ---, but there wouldn't be much point. We agree on all the other points (2,3,5,6). If you have specific ideas for the figures or the captions or the text, you could propose them here first so we can refine them together if you wish. Thanks for this interesting discussion in any case. MichelJullian 10:35, 18 June 2007 (UTC)[reply]

I realize (after I have already replied, as usual ;-) that your actual question in (4) was whether a non polarized device would have its anode and cathode reverted wrt a polarized device connected in its stead, the answer is no!!!!!! It's not that the definitions of A and C switch for a non polarized device, it's just that it simply doesn't have an anode and a cathode, just two uncommitted leads which you can connect either way without changing the behavior, e.g. a resistor or a parallel plate capacitor doesn't have an anode or a cathode. MichelJullian 11:05, 18 June 2007 (UTC)[reply]

Having said that, it occurs to me that a symmetrical electrolytic cell (e.g. with both electrodes made of carbon) would be a non polarized device, although there is no doubt it has an anode and a cathode. So by your fault we now have to find a replacement for "polarized", which would fit a symmetrical electrolytic cell but wouldn't fit a resistor :-) Or we remove the "polarized" altogether, but then people may think a resistor features an anode and a cathode. I don't know which is best, what do you think? MichelJullian 11:21, 18 June 2007 (UTC)[reply]

I have read your last three entries, but for the moment I want to focus on the first. I don't know how what I am going to say relates to what you wrote; I just want to clarify a point. In rereading your first comment I realized that my conception of a spark gap being equivalent, in a certain sense, to a CRT, was wrong. Simply cutting a wire would give CRT behavior for both types of relative voltage between the two sides of the cut, if the two ends of the wire were identical. (If they were nearly the same, both would give CRT behavior, but the smaller tip would eject electrons at a higher rate, for a given applied voltage, because of the larger field at the tip.) To get an ART, one would have to make one of the sides very flat; solder a flat plate on the left end of the cut, to face the sharp tip of the cut wire on the right. If the tip is negative, then electrons will be ejected, at a certain rate for a given voltage. If the tip is positive, then positive ions (characteristic of the anode) will be ejected, but the same rate of ejection (assuming valence +1) would require a much higher voltage than for electrons. At any rate, I now realize that a CRT has to be more complex than my simple version of a wire with a symmetrical cut.

OK. A resistor or a parallel plate capacitor has neither an anode or a cathode (except perhaps at very large applied voltages, where physical inequivalence of the two sides might matter). Got it.

I agree that a symmetrical electrolytic cell presents a problem.

I would want to read what Faraday has to say about cathode and anode in his evacuated cell experiments. If he uses the same definition as you, then I would feel confident that I know the correct general definition. Would you know of an online source for that? What bothers me is that I was taught which was the "correct" cathode in a CRT, but I never got the proper reason. Where did you learn the definitions? It has taken me a long time to understand how chemists think, and it was painful to try to understand your points.

By the way, I get the impression that most younger chemists don't know how the definitions of oxidation and reduction came about. But see http://www.scienceclarified.com/Oi-Ph/Oxidation-Reduction-Reaction.html, which I looked up just before I sent this message off. Sandman42 165.91.181.78 00:01, 20 June 2007 (UTC)[reply]

I learned the definitions on Wikipedia actually, except they were in terms of electron flow at the time. As discussed on this page I put them in terms of current (i.e. the opposite direction) to allow for ionic current etc. I then found Faraday's original work (ref to Gutenberg.org copy at the bottom of the articles, where you may also find some of his work on vacuum devices), and found he had also defined A and C in terms of current (cf etymology sections of A and C). MichelJullian 13:38, 20 June 2007 (UTC)[reply]

I added a bit about external to the cell vs. internal to the cell in anode to clear up some of the positive/negative confusion. I also added a bit about flow of electrons vs. electrical flow diagrams in the hopes of clearing the air a bit. Jonathan888 01:16, 26 October 2005 (UTC)[reply]

There was a recent edit which removed the mention of electrolytic solution from the main definition of anode... I reverted that edit and am noting here in case anyone wants to discuss it. I believe that it actually belongs in the definition because Faraday's naming convention was based on his original electrolytic cell.Jonathan888 (talk) 18:47, 6 December 2006 (UTC)[reply]

Hi Jonathan, thanks let's discuss the current definition: "An anode (from the Greek anodos = 'going up') is the electrode in a device that electrons flow out of to return to the circuit. Literally, it is the path through which the electrons ascend out of an electrolyte solution. The other charged electrode in the same cell or device is the cathode." In Greek, Anodos is 'the way up' actually. An electrode being literally an 'electron way', anode thus means 'the way up for electrons'. The way up in Faraday's beakers was the way out of course, so what he meant was indeed the above. However electrons are only one of the many possible charge carriers for electric current. Also, it could be understood from this definition that an electrolyte is necessarily involved. Therefore I suggest: "Anode: electrode through which electric current flows into a device. For example in a galvanic cell the anode is the negative electrode (cf drawing: electrons flow out i.e. current flows in), in an electrolytic cell the positive one, in a diode the terminal where current is allowed in. Faraday originally coined the word from Greek 'anodos' (ana hodos, the way up) for the electrode (elektron hodos, electron way) in an electrochemical cell where electrons flow up, i.e. out of the cell considering the device geometry. The other charged electrode in the same cell or device is the cathode." Comments/critics welcome of course, I will do the change in a few days if there are no objections. For the record I had proposed that mnemonic I found useful (ACID, Anode Current Into Device) but it was edited out on the grounds of it being an original creation rather than encyclopedic knowledge, oh well now people can find it at least in this discussion page :) MichelJullian 01:01, 10 December 2006 (UTC)[reply]

Hi Michael, I am very concerned based on my experiences editing and helping with this page that changing the definition to be based on electrical current will make it almost impossible to understand... read through this talk page and you should see what I mean. The problem is basically that electricians treat electricity as a positive force that flows from the positive terminal or contact. The physics reality is that negative electrons are drawn to a positive charge. The only way I've found to unobsfucate this confusion is to follow the teaching lead of some physics instructors and talk about the actual direction of flow of the electrons.Jonathan888 (talk) 18:38, 11 December 2006 (UTC)[reply]

Also, we should haul up user User:Heron and get his input... he's done a lot of work here.Jonathan888 (talk) 18:40, 11 December 2006 (UTC)[reply]

Being a physicist I would agree if the physics reality was as you suggest, but reality is more varied than that: an electric current (flow of charge) can be carried by all varieties of charged particles not just electrons and not just negatively charged particles, cf [[1]]. For example the Zn++ ions flowing from the anode into the electrolyte in the drawing are the charge carriers for that part of the current loop, no electrons involved there. Even the external part of the current loop could use positive charge carriers only instead of the electrons in the drawing, e.g. if the load of the galvanic cell was a point to plane corona discharge in Argon with the cell's anode as the plane, the carriers would be Ar+ ions flowing in from the positive point. I hope I have convinced you that electric current is more general than electron flow, and that the main definition should be as general as possible, and as simple as possible (but not simpler!). Electron flow should be mentioned also, if only for the origin of the word (the way up for electrons). Note the Columbia Electronics Encyclopedia, among others, also defines the anode more generally in terms of current flow: [2]. I'll wait for objections for another few days before implementing the changes MichelJullian 01:05, 12 December 2006 (UTC)[reply]

Micheal, the special case electrical carriers ONLY happen within the device with the electrodes - for the rest of the metallic circuit it is electron flow. Please don't make the article unreadable for anyone without a physics degree. All of the special cases are mentioned in the subarticles, it doesn't negate the fact that electrons are the carriers from the contacts to the circuit.Jonathan888 (talk) 18:12, 12 December 2006 (UTC)[reply]

Please check the current edit and see if you can live with it.Jonathan888 (talk) 21:28, 12 December 2006 (UTC)[reply]

Thanks Jonathan and Heron for the improvements, but some things are still wrong: "path through which the electrons ascended out of an electrolyte solution". A closer look at the galvanic cell drawing will show you that no electrons whatsoever ascend out of the solution, instead one Zn++ descends into the solution. It generates the same current(direction included) as the two electrons sent out to the external circuit mind you, which BTW leaves no room for negative ion involvement in the internal current, this will have to be corrected too. The etymology must be based on electrons rising _out of the cell_. Also the "oppositely charged" thing needs fixing, a cathode being defined as a terminal through which current flows the other way rather than in terms of polarity. Shall I let you do the rewording? MichelJullian 14:05, 13 December 2006 (UTC)[reply]

Come on, please consider it: it's a net equation... Zn++ and (-)(-) all the ionic flow is INTERNAL to the device. Talking about electrical current and direction consistently obsfucates and confuses to the point that people cry; this talk page is a case in point. Jonathan888 (talk) 20:43, 13 December 2006 (UTC)[reply]

Let's agree to disagree on this current vs electrons issue for now, and let's discuss the other points one at a time, do electrons ascend _out of the electrolyte solution_ Jonathan? MichelJullian 01:34, 14 December 2006 (UTC)[reply]

Apparently Faraday chose to describe it that way... thus the greek work he used to describe the process. Electrons are freed from the zinc anode and flow into the circuit - is the zinc anode part of the device? I would consider it part of the device with the electrodes but it's kind of semantics isn't it? Jonathan888 (talk) 16:40, 14 December 2006 (UTC)[reply]

Part of the device yes indeed, part of the solution (the liquid), no :) The 'ana hodos' 'elektron hodos' means the electrons ascend _out of the device_, no need to say they ascend _out of the electrolyte solution_, which they don't. As a matter of fact no electrons flow from the cathode to the anode internally as incorrectly stated in the 'electron flow' section, not even carried by negative ions, not a single one. The Zn++ ions must do the entire charge carrying job to satisfy Faraday's law. I see Heron has now come down on the conventional current side.I have already proposed a practice definition in my first post above, maybe we could elaborate on that? MichelJullian 00:41, 15 December 2006 (UTC)[reply]

The talk of electrons rising from the solution (which is the net effect of the device, but seems to be a real sticking point in discussing this) is limited to Faraday's device from whence the names came. Re-read the opening paragraph and it has been disambiguated to the point where a junior high student like my 11 year old son is able to understand it. The article does clearly state that it is a NET movement of electrons, not electrons themselves moving through the solution. I'm not sure where you are drawing the conclusion that Heron decided upon conventional current as being the way to describe this... please elaborate. Jonathan888 (talk) 20:00, 16 December 2006 (UTC)[reply]

Having read further down on the talk page and agreeing generally with all of Heron's points, and being out of time and patience... I'm throwing up my hands and walking away, feel free to bugger up the articles however suits your needs. In my experiences, electronically, chemically and physically the only way I've been able to keep things sorted out was following electron flow but that's just me... Jonathan888 (talk) 21:40, 16 December 2006 (UTC)[reply]

Implemented changes in anode article, as discussed. MichelJullian 13:34, 17 December 2006 (UTC)[reply]

Which is right? is anode negative? or positive? does the anode attract anions or cations? i thought that the negative electrode was ALWAYS the cathode, and I have textbooks that say so, but there's enough confusion here to twiddle anyone up. What's the right answer?

Quote:As it stands now, on the one page: