Capacitors -- charging and discharging

In summary: Rises exponentially is the correct and precise term! 'Asymptotic' is unnecessary and misleading. Some 'asymptotic' curves are not exponential.
  • #1
Hannah7h
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0
So, is this true for when a capacitor charges through a fixed resistor (as shown in the image below, when the switch is closed to 1)- the potential difference across the resistor exponentially decreases to zero and the potential difference across the capacitor exponentially increases from zero to equal the voltage across the battery (power supply), when the capacitor is fully charged?
Screen Shot 2016-06-06 at 18.54.30.png
 
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  • #2
Hannah7h said:
So, is this true for when a capacitor charges through a fixed resistor (as shown in the image below, when the switch is closed to 1)- the potential difference across the resistor exponentially decreases to zero and the potential difference across the capacitor exponentially increases from zero to equal the voltage across the battery (power supply), when the capacitor is fully charged?
View attachment 101750
Yes.
 
  • #3
cnh1995 said:
Yes.

Ok, so now if the switch is moved to position 2 and the capacitor is now discharging. The potential difference of the capacitor will now decrease exponentially, and so does the potential difference across the fixed resistor- why does the p.d across the fixed resistor also decrease?
 
  • #4
Also, when switch is in position 1, you could say voltage across the cap rises asymptotically to battery voltage.

When switch is in position 2, you can then think of the capacitor as a power supply -- where the voltage drops as you draw current out of it.
 
  • #5
Hannah7h said:
Ok, so now if the switch is moved to position 2 and the capacitor is now discharging. The potential difference of the capacitor will now decrease exponentially, and so does the potential difference across the fixed resistor- why does the p.d across the fixed resistor also decrease?
Capacitor acts as a source while discharging and voltage across capacitor is equal to the voltage across resistor. Since capacitor voltage is decreasing, voltage across the fixed resistor is also decreasing.
 
  • #6
In other words, resistor does not store any charge. Hence, voltage across the resistor decreases while discharging of the capacitor.
 
  • #7
cnh1995 said:
Capacitor acts as a source while discharging and voltage across capacitor is equal to the voltage across resistor. Since capacitor voltage is decreasing, voltage across the fixed resistor is also decreasing.

Ohhh I see that makes sense, just one more question why in: VC= -VR is the p.d across the resistor quoted as a negative value?
 
  • #8
David Lewis said:
Also, when switch is in position 1, you could say voltage across the cap rises asymptotically to battery voltage.

When switch is in position 2, you can then think of the capacitor as a power supply -- where the voltage drops as you draw current out of it.

Ah ok yes this makes sense now
 
  • #9
Hannah7h said:
Ohhh I see that makes sense, just one more question why in: VC= -VR is the p.d across the resistor quoted as a negative value?
It follows from KVL i.e. Vc+Vr=0. Going along the direction of current, you'd see a drop in potential across the resistor and a gain of potential across the capacitor.
 
  • #10
cnh1995 said:
It follows from KVL i.e. Vc+Vr=0. Going along the direction of current, you'd see a drop in potential across the resistor and a gain of potential across the capacitor.

Ok yeah makes sense, so when the capacitor is discharging the p.d across the capacitor increases so the p.d across the resistor decreases in order to = zero. And then when the capacitor discharges VC= -VR as both the p.d across the capacitor and p.d across the resistor decrease to zero.
 
  • #11
Hannah7h said:
Ok yeah makes sense, so when the capacitor is discharging **charging** the p.d across the capacitor increases so the p.d across the resistor decreases in order to = zero
Hannah7h said:
And then when the capacitor discharges VC= -VR as both the p.d across the capacitor and p.d across the resistor decrease to zero.
Right.
 
  • #12
cnh1995 said:
Right.

Sorry my mistake! and ok good, thanks for the help!
 
  • #13
Hannah7h said:
Sorry my mistake! and ok good, thanks for the help!
You're welcome!
 
  • #14
David Lewis said:
Also, when switch is in position 1, you could say voltage across the cap rises asymptotically to battery voltage.

When switch is in position 2, you can then think of the capacitor as a power supply -- where the voltage drops as you draw current out of it.

Rises exponentially is the correct and precise term!
'Asymptotically' is unnecessary and misleading.
Some 'asymptotic' curves are not exponential.
If the charging/discharging curves of capacitors were described as 'asymptotic' in an exam answer it would be marked wrong !
Take care with terminology!
 
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Likes davenn

1. How does a capacitor charge and discharge?

A capacitor charges by storing electrical energy between two conductive plates separated by an insulating material, or dielectric. When a voltage is applied to the capacitor, one plate becomes positively charged while the other becomes negatively charged. This creates an electric field between the plates, causing them to store energy. The capacitor discharges when the voltage source is removed, and the stored energy is released as a current.

2. What factors affect the charging and discharging of a capacitor?

The charging and discharging of a capacitor can be affected by several factors, including the capacitance of the capacitor, the voltage applied, the resistance of the circuit, and the type of dielectric used. The capacitance determines how much charge the capacitor can store, while the voltage and resistance affect the rate of charging and discharging. The type of dielectric can also affect the capacitance and the speed of charging and discharging.

3. How long does it take for a capacitor to charge and discharge?

The time it takes for a capacitor to charge and discharge depends on the capacitance, voltage, and resistance of the circuit. A larger capacitance will take longer to charge and discharge, while a higher voltage and lower resistance will result in a faster charging and discharging time. The type of dielectric can also affect the speed of charging and discharging.

4. Can a capacitor discharge on its own?

Yes, a capacitor can discharge on its own due to leakage current. Over time, the insulating material between the plates of a capacitor can break down, allowing a small amount of current to flow through the capacitor, causing it to discharge. This process is known as self-discharge and can affect the overall performance of a capacitor.

5. What are some practical applications of charging and discharging capacitors?

Capacitors have many practical applications, including storing energy in electronic devices, filtering out noise signals in audio equipment, and providing a temporary power supply during power outages. They are also used in flash photography, defibrillators, and power factor correction in electrical systems. Capacitors are essential components in many electronic devices and play a crucial role in various industries, such as telecommunications, automotive, and aerospace.

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