Capacitor in Circuit: Charging Globe & Dimming Light

  • Thread starter Thread starter forevermoreOC
  • Start date Start date
  • Tags Tags
    Capacitor Circuit
AI Thread Summary
When a capacitor is connected in series with a globe and charged by a battery, the globe initially glows brightly but dims as the capacitor reaches its maximum charge due to a decrease in current. The dimming occurs because the current flowing through the circuit drops as the capacitor stores charge. In a discharging scenario, the current and charge can be calculated using the discharge equation V = Vo e^-t/τ, which shows that both current and charge decrease exponentially over time. The relationship between the capacitor's charge and the globe's brightness is directly linked to the current flow, which diminishes as the capacitor charges. Ultimately, the behavior of the circuit illustrates the fundamental principles of capacitors in electrical circuits.
forevermoreOC
Messages
15
Reaction score
0
Is it true that when a capacitor is connected in series with a globe, and is charged with a battery that while the charge on the capacitor is being increased, the globe will glow brightly. But when the capacitor reaches its maximum charge, the globe will get dimmer, because of the loss of current through the capacitor?
 
Physics news on Phys.org
It starts off full brightness and starts dimming more and more as the charge is stored on the capacitor.
 
But it starts dimming because of the loss in current, right?
 
Right, the current drops as the charge is stored on the capacitor.
 
thankyou whozum
 
By the way, with a capacitor that is dishcharging in a similar circuit, what formula can you use to find the current through the globe after a certain time, and the charge that is on the capacitor after a certain time?
 
Basically you have a series RC circuit (where R is the globe's resistance) using the discharge equation V = Vo e^-t/τ (where τ = RC)
and substituting q/C for V and qo/C for Vo where qo is the initial charge on the capacitor you get an equation of the same form q = qo e^-t/τ. Therefore the charge also decreases exponentially. By differentiating the previous equation w.r.t time (i = dq/dt) you get i = -qo/τ e^-t/τ same with the current! (- implies current decreases with time)
 
Capacitors store charges.When connected in a circuit , it takes care of its own job irrespective of others do or not. So when you connect it with a battery , current starts flowing in the circuit , through the capacitor and the globe(which is a type of resistor in true sense) , so with time capacitor keeps on charging and the current keeps falling with time.As the current falls , the brightness in the globe keeps on lowering down , eventually leading to the dusk of the globe.

BJ
 

Similar threads

Why Do Capacitors Behave Differently in Series and Parallel Configurations?
Replies
20
Views
2K
Final Charge of a Capacitor in a Circuit with Capacitors and Resistors
Replies
9
Views
2K
LC oscillations - two capacitors and an inductor
Replies
15
Views
543
Ranking charge stored on three capacitors by a battery
Replies
6
Views
3K
Determining Inductance L in an LC Circuit
Replies
5
Views
2K
Finding Current in Resistors & Charge of Capacitor
Replies
4
Views
2K
Question about charged capacitors and inserting a dielectric into one
Replies
3
Views
1K
Determining Current Direction in a Charging RC Circuit
Replies
1
Views
2K
Capacitor Questions Charging and Discharging
Replies
4
Views
3K
Potential difference between 2 points in a capacitor circuit
Replies
30
Views
2K

Hot Threads

Recent Insights

Back
Top