Two charges, q1=-11.5nC and q2=28.5nC, are separated by a distance d=3.00cm [Free] B115
Two charges, q1=-11.5nC and q2=28.5nC, are separated by a distance d=3.00cm as shown in the figure. Determine the following. (a) the electric potential (in kV ) at point A kV (b) the electric potential (in kV ) at point B, which is halfway between the charges kV
![Two charges, q1=-11.5nC and q2=28.5nC, are separated by a distance d=3.00cm [Free] B115](data:image/svg+xml,%3Csvg%20xmlns='http://www.w3.org/2000/svg'%20viewBox='0%200%20640%20298'%3E%3C/svg%3E)
Answer
🔷 Electric Potential Due to Two Point Charges
🧪 Concept Overview
The electric potential at a point due to a point charge is a scalar quantity. It represents the electric potential energy per unit charge at that point.
V = (k × q) / r
- V = Electric potential in volts (V)
- k = Coulomb’s constant = 8.99 × 10⁹ Nm²/C²
- q = Charge in coulombs (C)
- r = Distance from the charge to the point (in meters)
📌 Given:
- q₁ = –11.5 nC = –11.5 × 10⁻⁹ C
- q₂ = 28.5 nC = 28.5 × 10⁻⁹ C
- Distance from each charge to Point A: d = 3.00 cm = 0.0300 m
🔹 Electric Potential at Point A
Using the principle of superposition:
VA = (k × q₁) / d + (k × q₂) / d
Substituting values:
- VA1 = (8.99 × 10⁹ × –11.5 × 10⁻⁹) / 0.0300 = –3446.2 V
- VA2 = (8.99 × 10⁹ × 28.5 × 10⁻⁹) / 0.0300 = 8540.5 V
Total potential at Point A:
🔹 Electric Potential at Point B (Midpoint)
Point B is midway between the charges, so distance from each is 0.015 m.
VB = (k × q₁) / (d/2) + (k × q₂) / (d/2)
Substituting values:
- VB1 = (8.99 × 10⁹ × –11.5 × 10⁻⁹) / 0.0150 = –6892.3 V
- VB2 = (8.99 × 10⁹ × 28.5 × 10⁻⁹) / 0.0150 = 17081.0 V
Total potential at Point B:
📊 Final Results
| Point | Electric Potential (kV) |
|---|---|
| A | 5.09 |
| B | 10.19 |
🧠 Interpretation
- Point A: Equal distance from both charges, but since one is negative and one is positive, their effects partially cancel. The result is a moderate net potential.
- Point B: Closer proximity to both charges increases the effect. Dominance of the larger positive charge results in a much higher potential.
📚 Concept Expansion
- Electric potential is a scalar quantity, so it’s added algebraically.
- A positive charge contributes a positive potential; a negative charge contributes a negative potential.
- The closer the point to a charge, the higher the magnitude of its contribution (due to the 1/r relationship).
- The superposition principle is a fundamental concept when multiple charges are involved.
🧪 Applications
- Electronics: Understanding voltage and capacitor behavior.
- Physics Labs: Mapping electric potentials in space.
- Biophysics: Analyzing neuron membrane potentials.
- Simulation Software: COMSOL, MATLAB, ANSYS for electrostatic field visualization.
✅ Conclusion
This problem clearly demonstrates the use of Coulomb’s law to determine electric potential in a two-charge system. The scalar nature of potential and its dependence on distance and charge sign are crucial to arriving at the correct values.
Final Answers:
VA = 5.09 kV
VB = 10.19 kV