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Introduction

The statement "Every charge in the universe exerts a force on every other charge in the universe" is a bold but accurate representation of the principles of physics. One way to comprehend how a charge can impact other charges throughout space is by envisioning its influence as a field. This "influence" refers specifically to the electrostatic force that a charge can exert on another charge. However, when discussing fields, we need a quantity (either scalar or vector) that remains unaffected by the charge it acts upon and solely depends on the influence and spatial distribution.

To simplify matters, we can define the electrostatic field by considering the force exerted by a point charge on a unit charge. In other words, the electric field can be defined as the force per unit charge.

In order to detect an electric field generated by a charge q, we can introduce a test charge q0 and measure the force acting upon it.
Electric Field Calculations | Physics for JEE Main & Advanced
Thus the force exerted per unit charge is:
Electric Field Calculations | Physics for JEE Main & Advanced
Note that the electric field is a vector quantity that is defined at every pint in space, the value of which is dependent only upon the radial distance from q.
The test charge q0 itself has the ability to exert an electric field around it. Hence, to prevent the influence of the test charge, we must ideally make it as small as possible.
Thus,
Electric Field Calculations | Physics for JEE Main & Advanced
This is the electric field of a point charge. Also, observe that it exhibits spherical symmetry since the electric field has the same magnitude on every point of an imaginary sphere centred around the charge q.

Electric Field Calculations | Physics for JEE Main & Advanced

Electric Field due to Continuous Distribution of Charges

With the help of Coulomb’s Law and Superposition Principle, we can easily find out the electric field due to the system of charges or discrete system of charges. The word discrete means every charge is different and has the existence of its own. Suppose, a system of charges having charges as q1, q2, q3……. up to qn. We can easily find out the net charge by adding charges algebraically and net electric field by using the principle of superposition.

This is because:

  • Discrete system of charges is easier to solve
  • Discrete system of charges do not involve calculus in calculations
    Electric Field Calculations | Physics for JEE Main & Advanced

Electric Field Calculations | Physics for JEE Main & AdvancedConsidering the charge distribution as continuous, the total field at P in the limit Δqi → 0 is
Electric Field Calculations | Physics for JEE Main & Advanced
This means a combination of infinite point charges kept together forming a linear, surface or a volumetric shape constitutes a continuous charge system with linear, surface or volumetric charge density respectively.

Refer to the following figure:
Electric Field Calculations | Physics for JEE Main & AdvancedThus, there are three types of continuous charge distribution system.

1. Linear Charge Distribution: A body having a finite charge distributed along its length i.e. along one dimension will have a linear charge distribution. In this case, we define the Linear Charge Distribution denoted by lower case Greek letter lambda (λ).
Electric Field Calculations | Physics for JEE Main & AdvancedObserve the rod given above of length L, a charge of +Q is distributed along the length of the rod. A small element dl will have a charge dq on itself. In this case, we define linear charge density of the rod.
Electric Field Calculations | Physics for JEE Main & Advanced

dq = λdl [Charge on infinitely small element dl]
Q = ∫dq = ∫dl [Total charge on the rod]

2. Surface Charge Distribution: a body having a finite charge distributed along its area or surface will have a Surface Charge Distribution. In this case, we define the Surface Charge Distribution denoted by lower case Greek letter Sigma (σ).
Electric Field Calculations | Physics for JEE Main & AdvancedElectric Field Calculations | Physics for JEE Main & Advanced
dq = σdA [Charge on infinitely small element d A]
Q = ∫dq = ∫σdA [Total charge on the sheet]

3. Volume Charge Distribution: a body having a finite charge distributed along its volume will have a Volumetric Charge Distribution. In this case, we define the Volumetric Charge Distribution denoted by lower case Greek letter rho (ρ).
Electric Field Calculations | Physics for JEE Main & AdvancedElectric Field Calculations | Physics for JEE Main & Advanced
dq = ρdV [Charge on infinitely small volume element dV]
Q = ∫dq = ∫ρdV [Total charge on the body]

Linear Charge Density

When the charge is non-uniformly distributed over the length of a conductor, it is called linear charge distribution. It is also called linear charge density and is denoted by the symbol λ (Lambda).

Mathematically linear charge density is λ = dq/dl

The unit of linear charge density is C/m. If we consider a conductor of length ‘L’ with surface charge density λ and take an element dl on it, then small charge on it will be

dq = λl

So, the electric field on small charge element dq will be

Electric Field Calculations | Physics for JEE Main & Advanced

To calculate the net electric field we will integrate both sides with proper limit, that is

Electric Field Calculations | Physics for JEE Main & Advanced

Electric Field Calculations | Physics for JEE Main & Advanced

Fig: We take small element x and integrate it in case of linear charge density 


Surface Charge Density

When the charge is uniformly distributed over the surface of the conductor, it is called Surface Charge Density or Surface Charge Distribution. It is denoted by the symbol σ (sigma) symbol and is the unit is C/m2.

It is also defined as charge/ per unit area. Mathematically surface charge density is σ = dq/ds

where dq is the small charge element over the small surface ds. So, the small charge on the conductor will be dq = σds

The electric field due to small charge at some distance ‘r’ can be evaluated as  

Electric Field Calculations | Physics for JEE Main & Advanced

Integrating both sides with proper limits we get

Electric Field Calculations | Physics for JEE Main & Advanced

Volume Charge Density

When the charge is distributed over a volume of the conductor, it is called Volume Charge Distribution. It is denoted by symbol ρ (rho). In other words charge per unit volume is called Volume Charge Density and its unit is C/m3. Mathematically, volume charge density is ρ = dq/dv

where dq is small charge element located in small volume dv. To find total charge we will integrate dq with proper limits. The electric field due to dq will be

dq = ρ dv

Electric Field Calculations | Physics for JEE Main & Advanced

Integrating both sides with proper limits we get

Electric Field Calculations | Physics for JEE Main & Advanced

Electric Field Calculations | Physics for JEE Main & Advanced

Fig: We can easily find electric field in different geometries using charge distribution system

Steps to calculate Electric Field Intensity due to continuous charge body:
(i) Identify the type of charge distribution and compute the charge density λ, σ or ρ.

(ii) Divide the charge distribution into infinitesimal charges dq, each of which will act as a tiny point charge.

(iii) The amount of charge dq, i.e., within a small element dl, dA or dV is
dq = λ dl (charge distributed in length)
dq = σ dA (charge distributed over a surface)
dq = ρ dV (charge distributed throughout a volume)

(iv) Draw at point P the dE vector produced by the charge dq. The magnitude of dE is
Electric Field Calculations | Physics for JEE Main & Advanced

(v) Resolve the dE vector into its components. Identify any special symmetry features to show whether any component(s) of the field that are not canceled by other components.

(vi) Write the distance r and any trigonometric factors in terms of given coordinates and parameters.

(vii) The electric field is obtained by summing over all the infinitesimal contributions.
Electric Field Calculations | Physics for JEE Main & Advanced

(viii) Perform the indicated integration over limit of integration that includes all the source charges.

Electric Field calculation due to Uniformly Distributed Continuous Charge

(a) Electric Field on axis of a uniformly charged circular ring:
Electric Field Calculations | Physics for JEE Main & AdvancedConsider a uniformly charged circular ring with a total charge +Q distributed uniformly along its length. We need to evaluate the net electric field due to this charged ring at a point P which is located x distance from its centre on its axis.
Conclude that the charge is distributed linearly throughout the length of the ring, hence we will define linear charge density λ for this ring,
λ = Total charge on the ring/𝑇otal Length =Q/2πr
Now, we consider an infinitely small length element dl on the ring,
Infinitesimal charge on element dl,
dq = λdl
Now, we write the expression of Electric Field at point P due to dq
Electric Field Calculations | Physics for JEE Main & Advanced
This, infinitely small electric field vector will be inclined at an angle θ with the axis of the ring (x axis), as shown in diagram.
We need to imagine components of Electric Field Calculations | Physics for JEE Main & Advanced along the x and y axis i.e. Electric Field Calculations | Physics for JEE Main & AdvancedandElectric Field Calculations | Physics for JEE Main & Advanced
By resolvingElectric Field Calculations | Physics for JEE Main & Advancedwe get,
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
Observe and imagine, thatElectric Field Calculations | Physics for JEE Main & Advancedwill cancel out if we take each and every element of the ring into consideration.
Therefore net electric field at P,
Electric Field Calculations | Physics for JEE Main & Advanced
Now, by geometry,
Electric Field Calculations | Physics for JEE Main & Advanced
Thus,
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
Replacing with the value of λ defined above,
Electric Field Calculations | Physics for JEE Main & Advanced

(b) Electric field strength at a general point due to a uniformly charged rod:
As shown in figure, if P is any general point in the surrounding of rod, to find the electric field strength at P, again we consider an element on rod of length dx at a distance x from point O as shown in figure.

Electric Field Calculations | Physics for JEE Main & Advanced

Now if dE be the electric field at P due to the element, then it can be given as
Electric Field Calculations | Physics for JEE Main & Advanced
Here
Electric Field Calculations | Physics for JEE Main & Advanced
Now we resolve electric field in components. Electric field strength in x-direction due to dq at P is,
dEx = dEsin 𝜃
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
Here we have x = r tan 𝜃
and dx = rsec2 𝜃d𝜃
Electric Field Calculations | Physics for JEE Main & Advanced
Net electric field strength due to dq at point P in x-direction is
Electric Field Calculations | Physics for JEE Main & Advanced
or Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
Similarly, the electric field strength at point P due to dq in y-direction is
dEy = dEcos𝜃
Electric Field Calculations | Physics for JEE Main & Advanced
Again we have x = rtan 𝜃
And dx = rsec2 𝜃d𝜃
Thus we have,
Electric Field Calculations | Physics for JEE Main & Advanced
Net electric field strength at P due to dq in y-direction is
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
Thus electric field at a general point in the surrounding of a uniformly charged rod which subtends angles 𝜽1 and 𝜽2 at the two corners of the rod from the point of consideration can be given as In parallel direction,
Electric Field Calculations | Physics for JEE Main & Advanced
In perpendicular direction ,
Electric Field Calculations | Physics for JEE Main & Advanced

We can use this generalized finite relation to calculate the Electric Field due to following systems too:
(i) Infinitely long uniformly charged rod with charge density 𝜆:

Electric Field Calculations | Physics for JEE Main & Advanced

For infinite rod, 𝜃1 → 90° and 𝜃2 → 90°
Therefore, for infinitely long uniformly charged rod,
Electric Field Calculations | Physics for JEE Main & Advanced
While,
Electric Field Calculations | Physics for JEE Main & Advanced

(ii) Electric field due to semi-infinite wire:
For this case,
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced

(c) Electric field strength due to a uniformly surface charged disc:
If there is a disc of radius R, charged on its surface with surface charge density s C/m2, we wish to find electric field strength due to this disc at a distance x from the centre of disc on its axis at point P shown in figure.

Electric Field Calculations | Physics for JEE Main & Advanced

Note: Identify that the electric charge is distributed over the surface of the non-conducting disc, hence we would define a surface charge density σ for this disc.
σ = Total Charge/Total Area = Q/πR2

To find electric field at point P due to this disc, we consider an elemental ring of radius y and width dy in the disc as shown in figure. Now the charge on this elemental ring dq can be given as
dq = σ (dA)
where dA is the area of the ring element on the disc,
also we can imagine ring element to be a small rectangle with width dy. Thus,
dA = 2πydy
dq = σ(2πydy)
Now we know that electric field strength due to a ring of radius R. Charge Q at a distance x from its centre on its axis can be given as
Electric Field Calculations | Physics for JEE Main & Advanced
Here due to the elemental ring electric field strength dE at point P can be given as
Electric Field Calculations | Physics for JEE Main & Advanced
Net electric field at point P due to this disc is given by integrating above expression from O to R as
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
Now, using integration by substitution we can solve the above integral as,
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
By geometry,
Electric Field Calculations | Physics for JEE Main & Advanced
Hence,
Electric Field Calculations | Physics for JEE Main & Advanced
Please note that 𝜽 is the angle subtended by the disc at point P which is x distance far from the center.

Case: (i) If x < < R ⇒ cos 𝜽 → 1
Physically, this would mean that the disc has its radius R→ ∞, that is the disc can be effectively imagined as infinitely long sheet of charge,
Thus, Electric field due to infinitely long plane sheet of charge at a distance x would be,
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced
i.e. behaviour of the disc is like infinite sheet.

Case: (ii) If x > > R
Electric Field Calculations | Physics for JEE Main & Advanced
Now, using binomial approximation,
Electric Field Calculations | Physics for JEE Main & Advanced
i.e. behaviour of the disc is like a point charge.

Electric Field Strength due to a uniformly charged Hollow Hemispherical Cup:
Figure shows a hollow hemisphere, uniformly charged with surface charge density 𝜎 C/m2 . To find electric field strength at its centre C, we consider an elemental ring on its surface of angular width dq at an angle q from its axis as shown. The surface area of this ring will be
Electric Field Calculations | Physics for JEE Main & AdvanceddA = 2𝜋r × Rdθ
By geometry, dA = 2𝜋R sin 𝜃 × Rdθ
Charge on this elemental ring is
dq = 𝜎d𝐴 = 𝜎. 2𝜋R sin 𝜃 × Rdθ

Now due to this ring electric field strength at centre C can be given as,
Electric Field Calculations | Physics for JEE Main & Advanced
Electric Field Calculations | Physics for JEE Main & Advanced

Net electric field at centre can be obtained by integrating this expression between limits 0 to 𝜋/2.
Electric Field Calculations | Physics for JEE Main & Advanced
Hence, Electric Field intensity at centre C, due to uniformly charged nonconducting hemispherical shell is,
Electric Field Calculations | Physics for JEE Main & Advanced
Above given continuous charged systems are most frequently used ones. It is recommended to remember the procedure and results by heart.

Electric Field due to a Linear Charge Distribution using Gauss Law

Consider a straight infinite conducting wire with linear charge density of λ. Consider a point P at a distance r from the wire in space measured perpendicularly. The wire cross-section is cylindrical in nature, so the Gaussian surface drawn is also cylindrical in nature. The area of a cylindrical surface is equal to S = 2πrL.

Electric Field Calculations | Physics for JEE Main & Advanced

The total amount of positive charge enclosed in a cylinder is Q = λL
Our goal is to calculate the total flux coming out of the curved surface and the two flat end surfaces numbered 1, 2, and 3.
Flux through surface 1 is
φ1 = 0
Flux through surface 2 is
φ2 = 0
Flux through surface 3 is
φ3 =  Ecosθ × S
The field is uniform and its magnitude is E, so, the flux becomes,
φ3 =  E × 1 × 2πrL
Therefore, the total electric flux is calculated as
φ  =  φ1 +  φ2 +  φ3
φ  = 2πrLE
Now, from Gauss’s Law, this flux is equal to the net closed charge divided by the permittivity of the material. So,
φ  = λL/ε0
Substitute the value of the flux in the above equation and solving for the electric field E, we get
Electric Field Calculations | Physics for JEE Main & Advanced
This is the electric field intensity (magnitude) due to a line charge density using a cylindrical symmetry.

Conclusion

The following points can be concluded for the topic:

  • The density of electric field lines tells us about the electric field intensity at that point.
  • Electric field is the space where charged particles experience force of attraction or repulsion due to a source charge.
  • Linear charge density is the charge distributed per unit length along a line.
  • According to Gauss’s Law, the total flux due to a charge through a surface is equal to the total charge enclosed in the closed surface divided by the permittivity of the medium.
  • The electric field due to a line charge distribution makes use of a cylindrical Gaussian surface. The magnitude of the electric field at a point in space which is at a distance r from the wire is
    Electric Field Calculations | Physics for JEE Main & Advanced

Definition of Gaussian Surface

A Closed Surface in a three-dimensional space whose flux of a vector field is calculated, which can either be the magnetic field or the electric field or the gravitational field, is known as the Gaussian Surface.

Electric Field Calculations | Physics for JEE Main & Advanced

What is Electric Field Due to a Uniformly Charged Infinite Plane Sheet?

Let us consider an infinitely thin plane sheet that is uniformly charged with a positive charge. Let 𝜎 be the charge density on both sides of the sheet. At point P the electric field is required which is at a distance a from the sheet. Through point P, a Gaussian cylinder is drawn with the cross-sectional area of A.

Electric Field Calculations | Physics for JEE Main & Advanced

The following is the electric flux crossing through the Gaussian surface:
Φ = E x area of the circular caps of the cylinder
The electric lines of force and the curved surface of the cylinder are parallel to each other. Therefore, the flux due to the electric field of the plane sheet passes through the two circular caps of the cylinder.
Φ = E x 2A (eq.1)
From the Gauss theorem, we know that,
Φ = q/ε0
The charge enclosed by the Gaussian surface is given as,
q = 𝜎A
Therefore,
Φ = 𝜎A/ε0 (eq.2)
From eq.1 and eq.2,
E x 2A = 𝜎A/ε0
Therefore,
E = 𝜎/2ε0
The direction of an electric field will be in the outward direction when the charge density is positive and perpendicular to the infinite plane sheet.
The direction of an electric field will be in the inward direction when the charge density is negative and perpendicular to the infinite plane sheet.

The document Electric Field Calculations | Physics for JEE Main & Advanced is a part of the JEE Course Physics for JEE Main & Advanced.
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FAQs on Electric Field Calculations - Physics for JEE Main & Advanced

1. What is the electric field due to a linear charge distribution and how is it calculated using Gauss's Law?
Ans. The electric field due to a linear charge distribution can be calculated using Gauss's Law by considering a Gaussian surface that is a cylinder around the linear charge distribution. By applying Gauss's Law, the electric field can be found as E = λ / (2πε₀r), where λ is the linear charge density, ε₀ is the permittivity of free space, and r is the distance from the linear charge distribution.
2. How is the electric field due to a uniformly charged infinite plane sheet determined?
Ans. The electric field due to a uniformly charged infinite plane sheet can be calculated by considering a Gaussian surface that is a rectangular box with one face parallel to the plane sheet. By applying Gauss's Law, the electric field is found to be E = σ / (2ε₀), where σ is the surface charge density and ε₀ is the permittivity of free space.
3. How do you define a Gaussian surface in the context of electric field calculations?
Ans. A Gaussian surface is an imaginary surface that is used to apply Gauss's Law in order to calculate the electric field due to charge distributions. It is a closed surface that encloses the charge distribution of interest, and the electric field is determined by integrating the electric field over the surface of the Gaussian surface.
4. What are some examples of continuous distributions of charges that can be used to calculate the electric field using Gauss's Law?
Ans. Examples of continuous distributions of charges include linear charge distributions, surface charge distributions, and volume charge distributions. These distributions can be used to determine the electric field at a point using Gauss's Law by selecting an appropriate Gaussian surface that encloses the charge distribution.
5. How can Gauss's Law be applied to calculate the electric field due to a continuous distribution of charges?
Ans. Gauss's Law can be applied to calculate the electric field due to a continuous distribution of charges by choosing an appropriate Gaussian surface that encloses the charge distribution. The total electric flux through the Gaussian surface is related to the total charge enclosed by the surface, allowing for the determination of the electric field at a given point.
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