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Electrostatic Potential | Electricity & Magnetism - Physics PDF Download

Electric potential, in simple terms, is a way to describe how much electric energy a charged object has based on its position relative to other charged objects. It's similar to how we describe a ball's gravitational potential energy based on its height. Electric potential helps us understand how charges interact and move in electric fields. In this document, we will understand the mathematical interpretation of electric potential. 

Curl of Electric field

Consider a point charge at the origin, then the electric field at a distance r is given by,
Electrostatic Potential | Electricity & Magnetism - Physics Now we will calculate the line integral of this field from some point a to some other point:
Electrostatic Potential | Electricity & Magnetism - PhysicsIn spherical coordinates,
Electrostatic Potential | Electricity & Magnetism - PhysicsElectrostatic Potential | Electricity & Magnetism - Physics

Electrostatic Potential | Electricity & Magnetism - Physics

Electrostatic Potential | Electricity & Magnetism - Physics 
where ra is the distance from the origin to point a and rb is the distance to b.
Then integral around a closed path is zero i.e.
Electrostatic Potential | Electricity & Magnetism - PhysicsThis line integral is independent of the path. It depends on two endpoints.
Applying Stokes theorem, we get Electrostatic Potential | Electricity & Magnetism - Physics The electric field is not just any vector but only those vectors whose curl is zero. If we have many charges, the principle of superposition states that the total field is the vector sum of their fields:  

Electrostatic Potential | Electricity & Magnetism - PhysicsSo,

Electrostatic Potential | Electricity & Magnetism - PhysicsSince Electrostatic Potential | Electricity & Magnetism - Physicsthe line integral is independent of the path.
So, we can define a function
Electrostatic Potential | Electricity & Magnetism - Physicswhere ϑ is some standard reference point V and then depends only on the point r. It is called the electric potential.
The potential difference between two points a and b is

Electrostatic Potential | Electricity & Magnetism - Physics

Now, the fundamental theorem for gradients states that  

Electrostatic Potential | Electricity & Magnetism - Physics

Potential obeys the superposition principle. 

The potential of localized charges

The potential of a point charge q is Electrostatic Potential | Electricity & Magnetism - Physics where R is the distance from the charge.

The potential of a collection of point charges is Electrostatic Potential | Electricity & Magnetism - Physics 
For continuous volume charge distribution Electrostatic Potential | Electricity & Magnetism - Physics

The potential of line and surface charges are Electrostatic Potential | Electricity & Magnetism - Physics and 

Electrostatic Potential | Electricity & Magnetism - Physics

Example 1: Which one of these is an impossible electrostatic field?
Electrostatic Potential | Electricity & Magnetism - Physics

(a)
Electrostatic Potential | Electricity & Magnetism - PhysicsSo, Electrostatic Potential | Electricity & Magnetism - Physics is an impossible electrostatic field.
(b) Electrostatic Potential | Electricity & Magnetism - Physics so Electrostatic Potential | Electricity & Magnetism - Physics  is a possible electrostatic field. 

Example 2: Find the potential inside and outside a spherical shell of radius R, charge q. 

From Gauss's law the field  

Electrostatic Potential | Electricity & Magnetism - Physics
Potential outside ( r >R) is:
Electrostatic Potential | Electricity & Magnetism - Physics
Potential inside ( r <R) is:
Electrostatic Potential | Electricity & Magnetism - Physics
So potential inside the spherical shell is constant.  
Thus
Electrostatic Potential | Electricity & Magnetism - Physics

Example 3: Find the potential inside and outside a uniformly charged solid sphere whose radius is R and whose total charge is q.

From Gauss's law the field  
Electrostatic Potential | Electricity & Magnetism - Physics 
Potential outside ( r >R) is:
Electrostatic Potential | Electricity & Magnetism - Physics
Potential inside ( r <R) is:
Electrostatic Potential | Electricity & Magnetism - Physics
Electrostatic Potential | Electricity & Magnetism - Physics
Electrostatic Potential | Electricity & Magnetism - Physics

Example 4: Find the potential distance r from an infinitely long straight wire that carries a uniform line charge λ.

Since Electrostatic Potential | Electricity & Magnetism - Physics In this case, we cannot set the reference point at ∞ , since the charge 

itself extends to ∞ . Let’s set it at r =a

Then,
Electrostatic Potential | Electricity & Magnetism - Physics

The document Electrostatic Potential | Electricity & Magnetism - Physics is a part of the Physics Course Electricity & Magnetism.
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FAQs on Electrostatic Potential - Electricity & Magnetism - Physics

1. What is the significance of the curl of the electric field in electrostatics?
Ans. The curl of the electric field in electrostatics is zero, indicating that the electric field is conservative. This means that the work done by the electric field in moving a charge from one point to another is independent of the path taken, only dependent on the initial and final positions.
2. What are the electrostatic boundary conditions and why are they important?
Ans. The electrostatic boundary conditions refer to the relationship between the electric field and potential at the interface of two different mediums. They are crucial for determining the behavior of electric fields at boundaries, such as the behavior of charges on a conductor surface.
3. How is work and energy related to electrostatics?
Ans. In electrostatics, work is done when moving a charge against an electric field, and this work results in a change in the potential energy of the system. The work done is equal to the negative change in potential energy, showing the relationship between work, energy, and the electric field.
4. What are the basic properties of conductors in electrostatics?
Ans. Conductors in electrostatics have the property of allowing charges to move freely within them until they reach equilibrium. They also have the property of creating an electric field inside the conductor that is zero, and the charges reside only on the surface of the conductor.
5. How do electric field, potential, and boundary conditions relate in IIT JAM preparation?
Ans. Understanding the relationship between electric field, potential, and boundary conditions is crucial for solving problems in IIT JAM physics exam. These concepts are fundamental in electrostatics and are often tested in the exam to assess the candidate's understanding and application of these principles.
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