Circuit completion : is it necessary?

  • Thread starter AlchemistK
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In summary: In your example, one of the terminals of the battery (most likely the negative) was (edit: probably) fastened to the chassis framework of the car to use it as an intentional return path back to the source (the battery). It found it's way back to the battery through the metal parts of the car... It didn't drain itself into the ground through the tires, I assure you.
  • #1
AlchemistK
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It is known that a voltage must be applied around a closed circuit to make current pass through it. So that's why a bulb doesn't glow without connecting both terminals, right?

But, suppose only one terminal of the bulb is attached to a battery and the circuit is closed, the battery still has a higher charge relative to the bulb, so electrons must still go to the bulb, to even out the charge, so why doesn't the bulb glow,even if it is for a small time period?...or does it?
 
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  • #2
AlchemistK said:
But, suppose only one terminal of the bulb is attached to a battery and the circuit is closed,

That's a contradiction. If only one terminal is connected, the circuit is open, by definition.


AlchemistK said:
the battery still has a higher charge relative to the bulb, so electrons must still go to the bulb, to even out the charge, so why doesn't the bulb glow,even if it is for a small time period?...or does it?

No it doesn't. There is no place for the current to go if the ciruit is open. The electrons are already in the bulb. something needs to move them. If no potential difference is applied to the bulb then the electrons can't move. If only one terminal is connected to the bulb, you have not applied a potential difference to it.
 
  • #3
AlchemistK, I think you may have a misconception about how batteries work. Batteries are electrically neutral, they do not have a "higher charge relative to the bulb". What they have is a potential difference between the terminals. If you touch only one end of the bulb to one of the battery terminals then you have not put the potential difference across the bulb, so no current.
 
  • #4
Alright...i see.

So the bulb should light in the above case if instead of a battery, a negatively charged body is used?
 
  • #5
Now you're talking about static electricity... Not sure if enough "equalizing" current would flow to make the bulb flicker. I'm thinking probably not.
 
  • #6
Assuming that you had a huge amount of charge you might be able to get enough current to make it flicker for a brief moment. Or you could arrange it so that it would arc from the other end of the bulb, in which case you could definitely get a flash, but that is completing the circuit in a sense so it is kind of cheating.
 
  • #7
Evil Bunny said:
Now you're talking about static electricity... Not sure if enough "equalizing" current would flow to make the bulb flicker. I'm thinking probably not.
You can probably see this with fluorescent or maybe neon bulbs which need very little current to flicker. But I think you could make a case for the circuit being completed "through thin air" as it were.
 
  • #8
AlchemistK said:
So the bulb should light in the above case if instead of a battery, a negatively charged body is used?
That's the ideas behind a ground, i.e. Earth - which can act as an infinite sink for the other end of your circuit.
 
  • #9
DaveC426913 said:
That's the ideas behind a ground, i.e. Earth - which can act as an infinite sink for the other end of your circuit.

Can you please explain? You're not suggesting that you can drain a battery by connecting only one of the battery terminals to the Earth are you?
 
  • #10
Yes, he is, and yes, you can. It happens quite commonly. I used to have a car that would work well if you kept using it but if you let it sit for a week or two, the battery would drain- there was a short somewhere that was grounding the battery and draining it.
 
  • #11
I don't think so.

In your example, one of the terminals of the battery (most likely the negative) was (edit: probably) fastened to the chassis framework of the car to use it as an intentional return path back to the source (the battery). It found it's way back to the battery through the metal parts of the car... It didn't drain itself into the ground through the tires, I assure you.

You cannot drain a battery without completing a circuit from the positive terminal to the negative terminal.

Connecting a wire from one terminal of your battery to the earth, even if we drove a 10-foot ground rod into the Earth and hooked the wire to it, would not drain anything from the battery.

(Some kind of failure of the chemical reactions inside the battery could render it useless, but that's a different conversation)
 
  • #12
AlchemistK said:
It is known that a voltage must be applied around a closed circuit to make current pass through it. So that's why a bulb doesn't glow without connecting both terminals, right?

But, suppose only one terminal of the bulb is attached to a battery and the circuit is closed, the battery still has a higher charge relative to the bulb, so electrons must still go to the bulb, to even out the charge, so why doesn't the bulb glow,even if it is for a small time period?...or does it?

I guess you are thinking about steady currents here, not currents and voltages that vary with time (for example AC mains supply).

Actually you are right, some electrons do go into the buib, but this happens very fast. It would probably take only millionths of a second for the electric field to get into equlibrium and the electrons to stop moving again. You certainly wouldn't see the buib "glow", and in fact it would be very hard to measure what happened with voltages as small as a battery.

You can get visible effects from this sort of thing in experiments with static electricity (Google it!) but the voltages involved are thousands of times higher than a typical battery, and even then the amount of power is much to small to make a light bulb glow.
 
  • #13
Isn't everything in some way or another a closed circuit? So one side of the battery could be connected to earth, the other to air, so both of those materials have their conductivities. Not sure what to use for the cross-sectional area or the length of the circuit though to use the formula for resistance: [tex]R=\rho \frac{L}{A} [/tex]. But technically there should be some current and the battery will drain.

What if you bury a battery? If the Earth is a really good conductor then should it not drain very fast?
 
  • #14
There is no current flow until there is a complete circuit. Something needs to conduct from the negative to the positive terminal.

Current does not flow out of one terminal of the battery unless it is flowing into the other terminal of the battery. You cannot have one without the other.

If you buried a battery in the earth, the dirt between the terminals would very likely conduct enough to form this complete circuit and the battery would drain. If the battery had enough voltage, then the air between the terminals could conduct and we would see an arc that would violently drain the battery.

I repeat myself, but I need to say it again... We cannot drain the battery without a complete circuit. It will not happen until the loop from one terminal to the other is complete. We cannot take one wire buried into the ground and connect it to only one terminal of a battery and expect any current to flow. There is no potential difference between a single terminal and the ground. No potential difference means no current flow.
 
  • #15
AlephZero said:
Actually you are right, some electrons do go into the buib, but this happens very fast. It would probably take only millionths of a second for the electric field to get into equlibrium and the electrons to stop moving again.

I don't agree. There is no difference of potential between one terminal of a battery and a light bulb. I say nothing would happen.
 
  • #16
Evil Bunny said:
I don't agree. There is no difference of potential between one terminal of a battery and a light bulb. I say nothing would happen.

If you connect one end of a battery to a plate, and the other to a different plate, there will be flow of electrons until the potential difference of the plates is equal to the voltage of the battery.

So if you connect one end of the battery to one terminal of the light bulb, there should be flow of charge from that end of the battery to that end of the terminal, and the opposite charge will build up at the other end of the battery. When the potential between that other end of the battery and the terminal of the light bulb is equal to the voltage of the battery, flow will stop.
 
  • #17
RedX said:
If you connect one end of a battery to a plate, and the other to a different plate, there will be flow of electrons until the potential difference of the plates is equal to the voltage of the battery.

If you're talking about a capacitor, then yes, there is current flow. The opposite charges attract each other through the dielectric and the capacitor charges. The negative terminal releases electrons into the plate and the positive terminal accepts electrons from the other plate. electrons left the negative terminal and returned on the positive terminal. A complete circuit was made.

If you're just talking about a couple random metal plates on the ground, I don't think much of anything happened because there were not charges to attract them to each other... there was no circuit made so little or nothing flowed into or out of the plates.

RedX said:
So if you connect one end of the battery to one terminal of the light bulb, there should be flow of charge from that end of the battery to that end of the terminal, and the opposite charge will build up at the other end of the battery. When the potential between that other end of the battery and the terminal of the light bulb is equal to the voltage of the battery, flow will stop.

No. Nothing moves until the other end of the battery is also in contact with the other side of the bulb. There will be no flow of charge from one end of the battery to the terminal of the light bulb because there is no difference of potential. The positive terminal is neutral to the light bulb. Just like the negative terminal is neutral to the light bulb. Neither of the battery posts are attracted to the light bulb on their own.

The only thing the positive post of that battery is attracted to is the negative post of the same battery. It's not attracted to the ground. It's not attracted to any other battery. It's not attracted to the frame of a car, and it's not attracted to a light bulb. The only thing in the universe that positive post is attracted to is it's own negative post. That's it... nothing else.
 
  • #18
Evil Bunny said:
You cannot drain a battery without completing a circuit from the positive terminal to the niegative terminal.

Connecting a wire from one terminal of your battery to the earth, even if we drove a 10-foot ground rod into the Earth and hooked the wire to it, would not drain anything from the battery.
So you're suggesting I cannot get a shock by grabbing the positive terminal of a car battery while standing barefoot in a puddle of water.
 
  • #19
AlchemistK said:
...the battery still has a higher charge relative to the bulb, so electrons must still go to the bulb..

I shall humbly offer my layman's understanding of the issue. Your argument, if I understand correctly, is that a stream of electrons (in or out), from battery-terminal potential-equalizing, should give light to the bulb for at least a short while, when the bulb is connected by one terminal to one from the battery.

I would compare the bulb to a hydraulic engine. If you open for pressurized liquid to enter engine, while the exit flow-valve of engine is closed, you would get pressure in the engine, but no work would be done, as that depends of flow. There would be some compression of the liquid though, and this may allow some insignificant movement of the engine-rotor, as the pressures equalize through the engine.

How electrical charge compresses/expands in a lightbulb glow-wire is not known to me, but low volt DC will only make one, small adjustment of electron-numbers. A high volt ac-terminal would make the electrons compress and expand repeatedly, and faster, thus maybe make a glow of duration in a sensible (low-volt) bulb.

Magnetically induced AC in short circuit glow-wire will however make a bulb glow, entirely without terminals. Much better (and safer) party-trick. Maybe shortcircuit a normal bulb and lay it on an induction cooker-plate. General warnings, of course
 
  • #20
DaveC426913 said:
So you're suggesting I cannot get a shock by grabbing the positive terminal of a car battery while standing barefoot in a puddle of water.

Leaking from a cars battery occurs not because (-) is in the body of the car, but because (+) leaks to body, unintentionally.

And if you get a shock, negative pole would not be carried through the water and bare feet, but the body of the car. The car is insulated from the ground, normally, with rubber wheels.
 
  • #21
Vespa71 said:
Leaking from a cars battery occurs not because (-) is in the body of the car, but because (+) leaks to body, unintentionally.

And if you get a shock, negative pole would not be carried through the water and bare feet, but the body of the car. The car is insulated from the ground, normally, with rubber wheels.

Are you too suggesting that, if I grabbed the positive terminal of a car battery while standing barefoot in a puddle of water, I would not get a shock? Is that what you're saying?

Because that's what Evil Bunny is claiming in post 11:

Evil Bunny said:
You cannot drain a battery without completing a circuit from the positive terminal to the negative terminal.

Connecting a wire from one terminal of your battery to the earth, even if we drove a 10-foot ground rod into the Earth and hooked the wire to it, would not drain anything from the battery.
 
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  • #22
DaveC426913 said:
Are you too suggesting that, if I grabbed the positive terminal of a car battery while standing barefoot in a puddle of water, I would not get a shock? Is that what you're saying?

Would the potential between the positive terminal and the ground be 6 volts (assuming a 12 volt battery)?
 
  • #23
DaveC426913 said:
Are you too suggesting that, if I grabbed the positive terminal of a car battery while standing barefoot in a puddle of water, I would not get a shock? Is that what you're saying?

Because that's what Evil Bunny is claiming in post 11:

My co-worker next to me works on cars all the time and says that he touches the terminals on many occasions and NEVER gotten a shock from them. Even touching both terminals at the same time. Perhaps the resistance of the human body is too high?
 
  • #24
DaveC426913 said:
So you're suggesting I cannot get a shock by grabbing the positive terminal of a car battery while standing barefoot in a puddle of water.

You absolutely would not get shocked... not one little bit.

Put your volt meter leads on the positive post and the puddle of water.

0 volts I promise you.
 
  • #25
RedX said:
Would the potential between the positive terminal and the ground be 6 volts (assuming a 12 volt battery)?

if "the ground" means where you bolted the negative post to the metal car.. then you'd measure 12 volts across the positive and ANYTHING metal in the car.

If "the ground" means the actual ground you're standing on then you would measure 0V between that and the positive terminal.
 
  • #26
The danger from cars comes from getting your screw driver across the positive and another metal part of the car... This is because they attached the negative terminal to the metal frame of the car in order to intentionally create a chassis ground. They have intentionally created a return path with the metal parts of the car... this return path is returning the charge back to the source (the battery). Nothing is leaving the battery and ending up in the earth.
 
  • #27
AlchemistK said:
It is known that a voltage must be applied around a closed circuit to make current pass through it. So that's why a bulb doesn't glow without connecting both terminals, right?

But, suppose only one terminal of the bulb is attached to a battery and the circuit is closed, the battery still has a higher charge relative to the bulb, so electrons must still go to the bulb, to even out the charge, so why doesn't the bulb glow,even if it is for a small time period?...or does it?
It would heat filament a little... try doing it with neon bulb, it will actually glow if you apply the voltage to one lead. Especially noticeable with AC voltage, so the lamp would appear to be lit continuously.
Try it, hold neon bulb by the glass and connect one of leads to mains phase. VERY carefully not to kill yourself. Works well here (240v mains) . The bulb has capacitance.
 
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  • #28
Evil Bunny said:
The danger from cars comes from getting your screw driver across the positive and another metal part of the car... This is because they attached the negative terminal to the metal frame of the car in order to intentionally create a chassis ground. They have intentionally created a return path with the metal parts of the car... this return path is returning the charge back to the source (the battery). Nothing is leaving the battery and ending up in the earth.
Precisely. You must always take off any jewellery when working with car as the jewellery may get electrically heated, and you must disconnect negative terminal first AFAIK, so that you don't risk to short out with a wrench when you disconnect positive terminal.

Drakkith said:
My co-worker next to me works on cars all the time and says that he touches the terminals on many occasions and NEVER gotten a shock from them. Even touching both terminals at the same time. Perhaps the resistance of the human body is too high?
Yep, the skin resistance is too high, in particular. It is also voltage dependent. At 12 volts, its many tens thousand ohms, so the current is fraction of milliamp. That is why battery terminals are not protected, and your 120v or 240v mains are.

However, I recall hearing that some guy killed himself with 9v battery, by piercing the skin with electrodes.
 
  • #29
We are introducing capacitive coupling and induction into this conversation now and I hope it's not confusing the OP.

Yes, when we move into the realm of AC induction the electromagnetic fields will induce voltages into wires that are not physically connected to any voltage source... this is completely different than what was discussed in the OP.

If we get back to the DC circuit and the light bulb, and forget about capacitive coupling or induced voltages... We are talking about the very basics of electricity.

The laws of physics dictate that we need a complete circuit, a closed loop, for current to flow. If we are talking about a basic 12 volt battery, the loop must start at one terminal... and end up at the other terminal... If we start at one terminal and end up at some other point (like the earth, for example, or a mud puddle, or the metal frame of a car), then we have not closed the loop. We have not made it back to the other terminal. No current flowed.

If you somehow made current flow out of a post on a 12 volt battery without having it return on the other post, then I think you should probably start writing it up...
 
  • #30
Evil Bunny said:
We are introducing capacitive coupling and induction into this conversation now and I hope it's not confusing the OP.

Yes, when we move into the realm of AC induction the electromagnetic fields will induce voltages into wires that are not physically connected to any voltage source... this is completely different than what was discussed in the OP.

If we get back to the DC circuit and the light bulb, and forget about capacitive coupling or induced voltages... We are talking about the very basics of electricity.

The laws of physics dictate that we need a complete circuit, a closed loop, for current to flow. If we are talking about a basic 12 volt battery, the loop must start at one terminal... and end up at the other terminal... If we start at one terminal and end up at some other point (like the earth, for example, or a mud puddle, or the metal frame of a car), then we have not closed the loop. We have not made it back to the other terminal. No current flowed.

If you somehow made current flow out of a post on a 12 volt battery without having it return on the other post, then I think you should probably start writing it up...
He's not discussing DC though... he's asking what will happen when he connects the battery to the bulb, which is not a steady state, and he is absolutely right that the current will flow until potentials equalize, and it really is the case that neon bulb will lit up for a short time when he connects it. You can say in this case that the circuit is completed by capacitance between other battery terminal and the bulb.
 
  • #31
How is connecting a battery to a bulb not considered DC?

Not sure how you can have any capacitance between a battery post and a light bulb, but I suppose it could be a possiblity...
 
  • #32
Dmytry said:
He's not discussing DC though... he's asking what will happen when he connects the battery to the bulb, which is not a steady state, and he is absolutely right that the current will flow until potentials equalize, and it really is the case that neon bulb will lit up for a short time when he connects it. You can say in this case that the circuit is completed by capacitance between other battery terminal and the bulb.

That is DC. And what capacitance are you referring to?
 
  • #33
Alright, so the bulb WILL glow, even if it is for an undetectable period of time. Well since the bulb can glow, we can also get a shock, by just touching a high voltage source, without completing the circuit.

Right?
 
  • #34
No. Bulb won't glow. You won't get a shock if only one post of the battery is involved.
 
  • #35
Could we please get at one correct conclusion? someone said the bulb will glow.
 
<h2>1. Is circuit completion necessary for a circuit to function?</h2><p>Yes, circuit completion is necessary for a circuit to function properly. Without a complete circuit, electricity cannot flow and the circuit will not work.</p><h2>2. What happens if a circuit is not completed?</h2><p>If a circuit is not completed, electricity will not flow and the circuit will not work. This can result in a device or system not functioning properly or at all.</p><h2>3. How can I tell if a circuit is complete?</h2><p>You can tell if a circuit is complete by using a multimeter to measure the voltage and resistance of the circuit. If there is a complete path for electricity to flow, the multimeter will show a reading. You can also visually inspect the circuit for any breaks or disconnected components.</p><h2>4. Can a circuit be completed in different ways?</h2><p>Yes, there are different ways to complete a circuit. For example, a series circuit is completed when electricity flows through each component in a single path, while a parallel circuit is completed when electricity flows through multiple paths. Additionally, circuits can be completed using different materials such as wires, conductive metals, or even water.</p><h2>5. Why is circuit completion important in electronics?</h2><p>Circuit completion is important in electronics because it allows for the flow of electricity and enables devices to function. Without a complete circuit, electricity cannot flow and devices will not work. Additionally, understanding circuit completion is essential for troubleshooting and repairing electronic devices.</p>

1. Is circuit completion necessary for a circuit to function?

Yes, circuit completion is necessary for a circuit to function properly. Without a complete circuit, electricity cannot flow and the circuit will not work.

2. What happens if a circuit is not completed?

If a circuit is not completed, electricity will not flow and the circuit will not work. This can result in a device or system not functioning properly or at all.

3. How can I tell if a circuit is complete?

You can tell if a circuit is complete by using a multimeter to measure the voltage and resistance of the circuit. If there is a complete path for electricity to flow, the multimeter will show a reading. You can also visually inspect the circuit for any breaks or disconnected components.

4. Can a circuit be completed in different ways?

Yes, there are different ways to complete a circuit. For example, a series circuit is completed when electricity flows through each component in a single path, while a parallel circuit is completed when electricity flows through multiple paths. Additionally, circuits can be completed using different materials such as wires, conductive metals, or even water.

5. Why is circuit completion important in electronics?

Circuit completion is important in electronics because it allows for the flow of electricity and enables devices to function. Without a complete circuit, electricity cannot flow and devices will not work. Additionally, understanding circuit completion is essential for troubleshooting and repairing electronic devices.

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