Hi all,
The discussion is interesting but it's beyond me at this stage I know that battery is power source
the discussion is really confusing me. It would be easier for me to follow the thread if we can discuss about the circuit that I've setup in the breadboard with the picture that I've posted so I can follow the discussion again
Thank you for your help.
Cheers
Sorry to get so far off topic, Nick. I guess this really turned into more of an argument between members then helpful replies. I'm going to respond to Ratch's latest post, and then I'll stop my end of the argument.
DerStrom8,
Yes, but if the ion flow stops, so does the external electron flow.
Well yes, but that is not the point. I think you've completely lost track of what we're actually talking about here.
It is still a resistance. Not a commercial resistor, but still a resistance.
Sure, but a slab of a PNP semiconductor (which, by the way, is not just a "slab"--it's made up of three parts, but I'm hoping you already know that) has a lot more variables and factors that come into play, whereas a basic resistor does not. I'm using SIMPLE examples to try to help the OP, and IMHO, you're only making things more confusing for him.
I am calling the oxidizer, stabilizers, fillers, and anything else between the cathode and anode an electrolyte.
Now that's just plain wrong. The electrolyte is a specific element that strips the electrons from the oxidizer. You can't just pretend everything between the cathode and anode is an electrolyte--that's 100% incorrect. There are four main parts in a battery--The positive electrode, the oxidizer, the electrolyte, and the negative electrode. You can't just say that everything between the electrodes is the electrolyte--that's only a part of it.
I guess we are going to have to disagree about whether the electrolyte gives electrons to the anode and takes them back from the cathode. And whether electrons travel internally through the electrolyte instead of ion generation and ion neutralization occurring.
No need to disagree. They are both correct. When an atom loses an electron, it becomes positively charged, due to the fact that it now has more protons than electrons. This makes it a positive ion. The electrons, which were stripped from the oxidizer, flow through the electrolyte and are repelled from the negative electrode (like charges repel), flow through the circuit, and are pulled back into the cathode, where the positive ions are (opposite charges attract). Since the ions are positive, they pull on the negatively-charged electrons (and according to Newton's third law, "for every action, there is an equal but opposite reaction", this also causes the ions to move slightly towards the electrons at the cathode). Once the electrons return to the cathode, they are "reunited" with the ions, which are neutralized once again, and the process repeats. You probably ought to learn a little more about chemistry and how charges and ionized atoms work with each other before throwing out an argument against something that is saying the same thing as you are. Just saying
And if the electrons cannot move outside of the battery without ions moving inside the battery, then the ions are just as important.
Sure, they're just as important when it comes to making the battery actually work, but if someone is just trying to learn how current flows
through a circuit, there is absolutely no need to tell them about how current flows
just inside the battery.
Okay Nick, I've said my piece. Ratch can keep arguing all he wants, but I hope he can figure out from my posts where his assumptions are going wrong. I'll try not to respond to him anymore, and only to your questions.
Good luck
Best wishes,
Der Strom
