Definition, derivations, point charge potential, dipole potential, properties, solved examples and exam questions.
Electric potential at a point is defined as the work done per unit positive test charge in bringing that charge from infinity to the point without acceleration. The phrase without acceleration means the test charge is moved slowly, so that the external agent balances the electric force at every instant.
Here W is the work done by an external agent and q is a small positive test charge. Electric potential tells us how much electric potential energy each coulomb of charge would have at that point.
Potential difference between two points is work done per unit charge in moving the test charge from one point to the other. It is the useful measurable quantity in circuits and electrostatics.
If charge q moves through potential difference ΔV, the work associated with the movement is the product of charge and potential difference.
| Idea | Electric Potential | Electric Field |
|---|---|---|
| Physical meaning | Potential energy per unit positive test charge. | Force per unit positive test charge. |
| Formula idea | V = W/q | E = F/q |
| Nature | Scalar quantity; it has sign but no direction. | Vector quantity; it has magnitude and direction. |
| SI unit | volt, where 1 V = 1 J C-1 | newton per coulomb or volt per metre. |
| Superposition | Algebraic sum of potentials. | Vector sum of fields. |
Work and charge are scalar quantities, so their ratio is also scalar. A positive potential does not mean it points in a positive direction; it means a positive charge has positive potential energy there relative to the chosen zero level.
If 6 J of work is required to bring a 2 C positive test charge from infinity to a point, then V = W/q = 6/2 = 3 V. A 5 C charge placed at the same point would have potential energy U = qV = 15 J.
For a point charge Q, electric potential at a distance r is obtained by calculating the work done in bringing a unit positive charge from infinity to that point.
A positive source charge gives positive potential because positive external work is needed to bring a positive test charge closer against repulsion.
A negative source charge gives negative potential because the electric field attracts a positive test charge, so the external work for slow movement is negative.
The magnitude |V| = k|Q|/r decreases as distance increases and tends to zero at infinity.
If several charges are present, their potentials are added algebraically, taking signs of charges directly.
Electric potential connects field geometry with energy. If a charge is moved between two points, the potential difference determines how much work is required or released.
For slow movement, external work per unit charge equals change in potential.
The electric field does positive work when a positive charge naturally moves toward lower potential.
Potential energy of charge q at potential V is qV.
| Movement of positive charge | Potential change | Work by field | External work for slow motion |
|---|---|---|---|
| High potential to low potential | ΔV < 0 | Positive | Negative |
| Low potential to high potential | ΔV > 0 | Negative | Positive |
| Along equipotential | ΔV = 0 | Zero | Zero |
Electric potential is often easier than electric field because it is scalar, but its signs and reference level must be handled carefully.
Potential has sign but no direction. Add potentials algebraically.
Potential may be positive near positive charges, negative near negative charges, and zero at reference points or by cancellation.
For isolated charge distributions, infinity is usually chosen as the zero-potential reference.
Net potential is the algebraic sum of potentials due to all individual charges.
Electric field is the negative gradient of potential: E = -dV/dr or E = -∇V.
Electric field is perpendicular to equipotential surfaces and no work is done along them.
Inside a conductor in electrostatic equilibrium, electric field is zero and potential is constant.
Electric field points in the direction in which potential decreases fastest.
Only potential difference has direct physical meaning; absolute potential depends on chosen zero.
| Property | Exam implication | Common trap |
|---|---|---|
| Potential is scalar | Use simple algebraic addition. | Do not resolve potential into components. |
| Potential can be zero where field is nonzero | Dipole equatorial line is the standard example. | Zero potential does not prove zero electric field. |
| Potential inside conductor is constant | Every point inside and on the surface has same potential. | Do not use kQ/r for points inside the conductor. |
| Equipotential motion needs no work | Use W = qΔV = 0. | Path length does not matter if endpoints have same potential. |
For several point charges, potential is found by adding individual potentials algebraically. The distance used for each charge is the distance from that particular charge to the observation point.
V = k(q1/r1 + q2/r2). Include signs of charges.
Add three terms. If symmetry exists, combine equal-distance terms first.
At the centroid or a vertex, calculate separate distances from every charged vertex.
At the centre, each corner is at distance a/√2 for side a.
| Configuration | Observation point | Key formula |
|---|---|---|
| Two charges on a line | Point between or outside | Use actual distance from each charge. |
| Equilateral triangle | Centre or vertex | Use equal distances when symmetry allows. |
| Square of side a | Centre | Distance from each corner is a/√2. |
| Regular polygon | Centre | Equal distances make scalar addition very fast. |
An electric dipole consists of two equal and opposite charges +q and -q separated by a small distance 2a. Dipoles are central in electrostatics, molecular physics, polarization, and entrance exam problems.
Electric dipole moment points from negative charge to positive charge. Its SI unit is coulomb metre, written as C m.
CBSE focuses on definitions and derivations, NEET emphasizes formula recognition, and JEE often combines dipole potential with approximation, energy, and symmetry.
Let point P lie on the dipole axis at distance r from the centre. The positive charge is nearer, so its contribution has denominator r - a; the negative charge is farther, so its denominator is r + a.
At an equatorial point, the observation point is equally distant from +q and -q. The magnitudes of the two potentials are equal, but their signs are opposite.
For a point P at distance r from the centre of a short dipole and making angle θ with the dipole axis, the potential depends on the projection of dipole moment along the position vector.
Electric field is related to how rapidly potential changes with position. In one-dimensional radial motion, electric field is the negative rate of change of potential with distance.
The negative sign shows that electric field points toward decreasing potential.
In three dimensions, the gradient points toward increasing potential, so field is opposite to it.
Differentiating gives the familiar electric field magnitude.
An equipotential surface is a surface on which electric potential is the same at every point. Moving a charge along such a surface requires no work because the potential difference is zero.
All points on an equipotential surface have the same value of V.
W = qΔV. On an equipotential surface, ΔV = 0, so W = 0.
Electric field cannot have a tangential component along an equipotential surface; otherwise work would be done.
Point charge surfaces are concentric spheres; uniform field surfaces are parallel planes; dipole surfaces are more complex.
In electrostatic equilibrium, the electric field inside a conductor is zero. Therefore the potential does not change inside the conductor, and the whole conductor is an equipotential body.
| Region | Electric field | Potential |
|---|---|---|
| Inside conductor | Zero | Constant = kQ/R |
| On surface | Just outside: kQ/R2 | kQ/R |
| Outside conductor | kQ/r2 | kQ/r |
Charged droplet problems are common in NEET and JEE because they combine conservation of charge, conservation of volume, and the potential of a conducting sphere.
Volume is conserved: n(4/3)πr3 = (4/3)πR3.
Charges add directly when droplets merge.
Use V = kq/r, Q = nq, and R = n1/3r.
Question: Eight identical droplets each have potential 10 V. Find the potential of the larger drop.
Answer: 40 V
Question: Twenty-seven droplets each of radius r and charge q combine. Express final potential in terms of small droplet potential V.
Answer: 9V
Question: If 64 identical charged droplets combine, what is the radius of the new drop?
Answer: 4r
Question: How many identical droplets must combine to make final potential 16 times the original?
Answer: 64 droplets
Question: 125 droplets each of charge 2 nC and radius 1 mm combine. Find final charge and radius.
Answer: Q = 250 nC, R = 5 mm
Question: Each small droplet has potential 3 V. If 216 droplets combine, find new potential.
Answer: 108 V
Question: A large drop formed from 27 equal droplets has potential 180 V. What was each small droplet's potential?
Answer: 20 V
Question: A problem states identical droplets. Which quantities become n times, n1/3 times, and n2/3 times?
Answer: Charge n times, radius n1/3 times, potential n2/3 times
Question: If 1000 identical droplets combine, what is V'/V?
Answer: 100
Question: A charged droplet at potential V splits into 8 identical droplets. Find potential of each small droplet.
Answer: V/4
Use this formula sheet for quick revision before CBSE board exams, NEET, JEE Main, JEE Advanced, IB Physics, IGCSE, ICSE, A-Level, and UP Board exams.
These solved examples are designed to avoid repetition. Each example tests a different idea: definition, sign, superposition, dipole potential, conducting sphere, equipotential surface, work, energy, and charged droplets.
Question: A 3 C positive test charge is brought from infinity to a point. If 24 J work is done by the external agent, find the potential.
Answer: 8 V
Question: A charge of 5 C moves between two points with potential difference 12 V. Find the work done by the external agent for slow movement.
Answer: 60 J
Question: A 2 C charge is placed at a point where potential is 15 V. Find its potential energy.
Answer: 30 J
Question: Show that 1 volt is 1 joule per coulomb.
Answer: 1 V = 1 J C-1
Question: Two charges produce potentials +12 V and -5 V at the same point. Find net potential.
Answer: 7 V
Question: A 4 C charge moves on an equipotential surface. Find work done.
Answer: 0 J
Question: What is the sign of potential near an isolated negative charge?
Answer: Negative
Question: Find potential at 0.3 m from a 2 nC charge. Take k = 9 x 109 SI.
Answer: 60 V
Question: A charged conducting sphere has surface potential 200 V. What is potential at its centre?
Answer: 200 V
Question: A positive charge moves from 80 V to 20 V. Is work done by electric field positive or negative?
Answer: Positive
Question: At point P, potentials due to three charges are 20 V, -8 V and 3 V. Find net potential.
Answer: 15 V
Question: What is the potential at an equatorial point of an electric dipole?
Answer: 0
Question: A short dipole has p = 4 x 10-9 C m. Find axial potential at r = 2 m using k = 9 x 109.
Answer: 9 V
Question: If V = 40/r, find electric field magnitude at r = 2 m.
Answer: 10 N/C
Question: If 8 identical droplets combine, by what factor does potential increase?
Answer: 4 times
Question: A 6 nC charge creates potential at 0.2 m. Find V.
Answer: 270 V
Question: Find potential 0.5 m from a -4 nC charge.
Answer: -72 V
Question: A 2 microcoulomb charge moves through a potential difference of 300 V. Find work.
Answer: 6 x 10-4 J
Question: Two +2 nC charges are each 0.3 m from point P. Find potential at P.
Answer: 120 V
Question: +q and -q are at equal distance from P. Find net potential.
Answer: 0
Question: For short dipole, if distance from centre is doubled on axial line, how does potential change?
Answer: One-fourth
Question: For a short dipole, potential at angle 60 degrees is what fraction of axial potential at same r?
Answer: 1/2
Question: Potential at equatorial point of dipole is zero. Is electric field also zero?
Answer: No, electric field is not zero
Question: 27 droplets, each at potential 5 V, merge. Find final potential.
Answer: 45 V
Question: A conducting sphere has Q = 2 microcoulomb and R = 0.1 m. Find surface potential.
Answer: 1.8 x 105 V
Question: Two opposite charges are separated by r. What is sign of potential energy?
Answer: Negative
Question: A point has V = 0 due to two charges. What can be concluded about potential energy of a charge placed there?
Answer: Potential energy is zero
Question: A 10 microcoulomb charge moves along an equipotential line for 5 cm. Find work.
Answer: 0
Question: Potential decreases by 20 V over 0.5 m in a uniform field. Find field magnitude.
Answer: 40 V/m
Question: Four equal charges q are at corners of square side a. Find potential at centre.
Answer: 4√2 kq/a
Question: Charges +q, +q and -q are at vertices of an equilateral triangle of side a. Find potential at centroid.
Answer: √3 kq/a
Question: Charges +q, -q, +q, -q occupy consecutive corners of a square. Find potential at centre.
Answer: 0
Question: Two charges 3 microcoulomb and 2 microcoulomb are 0.6 m apart. Find potential energy.
Answer: 0.09 J
Question: If V = 100/r - 20, find electric field magnitude at r = 5 m.
Answer: 4 N/C
Question: A dipole has q = 2 microcoulomb, a = 0.1 m. Find exact axial potential at r = 0.5 m.
Answer: 1.5 x 104 V
Question: For a short dipole, potential at 120 degrees is what sign relative to axial positive side?
Answer: Negative, half in magnitude
Question: A conducting sphere has radius R and charge Q. Find potential at r = R/2.
Answer: kQ/R
Question: A large drop of potential 80 V breaks into 8 identical drops. Find potential of each small drop.
Answer: 20 V
Question: Give a configuration where potential is zero at a point but electric field is nonzero.
Answer: Equatorial point of a dipole
Question: A 1 mC positive charge moves from 100 V to 40 V. Find work done by field.
Answer: 0.06 J
Question: +8 nC and -2 nC are separated by 0.6 m. Find potential at midpoint.
Answer: 180 V
Question: Four charges at equal distance R from a point have charges q, 2q, -q, 3q. Find potential.
Answer: 5kq/R
Question: Potential increases along +x. What is direction of electric field?
Answer: Along -x
Question: Three charges q, q, q are placed at vertices of equilateral triangle side a. Find total potential energy.
Answer: 3kq2/a
Question: For a point charge, potential at A is 30 V at distance r. Find potential at 3r.
Answer: 10 V
Question: A thin ring of radius R carries charge Q uniformly. Find potential at centre.
Answer: kQ/R
Question: A uniformly charged ring of radius R and charge Q. Find potential at point on axis at distance x.
Answer: kQ/√(R2 + x2)
Question: Use ring axial potential V = kQ/(R2+x2)1/2 to find axial field.
Answer: kQx/(R2+x2)3/2
Question: Charges q, -q and q are at vertices of equilateral triangle side a. Find total potential energy.
Answer: -kq2/a
Question: Starting from exact dipole potential, justify the short dipole approximation.
Answer: Approximation valid when r >> a
Question: Can both potential and electric field be zero at a point? Give a possible symmetric case.
Answer: Yes, but both must be independently verified
Question: If V(x) = Ax2 + Bx + C, find electric field.
Answer: E = -(2Ax + B)
Question: Prove electric field is normal to equipotential surface.
Answer: Field is normal to equipotential surface
Question: Inside material of a charged conducting shell in electrostatic equilibrium, what is electric field and potential behavior?
Answer: E = 0 and V constant
Question: If every potential in a problem is increased by 50 V, what happens to electric field?
Answer: No change
Question: Potential changes from 200 V to 80 V along any path. Work done by field on 3 microcoulomb positive charge?
Answer: 3.6 x 10-4 J
Question: For a short dipole, at which angles is potential zero?
Answer: 90 degrees, equatorial plane
Question: A potential is V = kQ/r + C. What is physical role of C?
Answer: It changes reference level only
Question: Derive potential factor for n identical droplets merging.
Answer: V' = n2/3V
Question: Four charges q at square corners and charge -Q at centre. Find potential at a corner due to other charges.
Answer: k/a[2q + q/√2 - Q√2]
Question: A student says volt is newton per coulomb. Correct the statement.
Answer: 1 V = 1 J/C
Question: A 2 C charge gains 10 J energy. Find potential difference.
Answer: 5 V
Question: Why is work done along an equipotential surface zero?
Answer: Because ΔV = 0
Question: For V = kQ/r, describe the shape of V against r for Q > 0.
Answer: Positive decreasing hyperbola
Question: Explain why potential is scalar although electric field is vector.
Answer: Potential is scalar
Question: A charge 0.5 C moves across 6 V. Find energy transferred.
Answer: 3 J
Question: What is potential inside a charged conductor?
Answer: Constant
Question: Two potentials at a point are +30 V and -45 V. Find resultant potential.
Answer: -15 V
Question: At the equatorial point of a dipole, why is potential zero?
Answer: Equal and opposite scalar contributions cancel
Question: If potential decreases uniformly by 12 V over 0.04 m, find field strength.
Answer: 300 V/m
Question: Write the definition of electric potential and its formula.
Answer: V = W/q
Question: Define one volt.
Answer: 1 volt = 1 joule per coulomb
Question: State potential due to point charge Q at distance r.
Answer: V = (1/4πε0)Q/r
Question: Write formula for potential energy of two point charges.
Answer: U = kq1q2/r
Question: State two properties of equipotential surfaces.
Answer: Same potential; zero work; perpendicular field
Question: Define electric dipole moment.
Answer: p = q(2a), from -q to +q
Question: Write short dipole potential on axial line.
Answer: V = kp/r2
Question: What is potential on equatorial line of a dipole?
Answer: 0
Question: Write potential inside a charged conducting sphere.
Answer: V = kQ/R
Question: If n identical charged drops combine, write new potential.
Answer: V' = n2/3V
This question bank contains exam-style questions. No fake year labels are used. Each answer is clickable and includes the correct answer with explanation.
Electric potential at a point is best described as:
Correct Answer: B. Work done per unit positive charge
Solution: Electric potential is defined as work done per unit positive test charge in bringing it from infinity to the point without acceleration.
A negative point charge produces which type of potential at a nearby point?
Correct Answer: C. Negative
Solution: V = kQ/r, and r is positive. If Q is negative, V is negative.
Potential at the equatorial point of an electric dipole is:
Correct Answer: C. Zero
Solution: The point is equally distant from both charges, so equal and opposite scalar potentials cancel.
If 64 identical droplets merge, final potential becomes:
Correct Answer: C. 16V
Solution: V' = n2/3V = 642/3V = 16V.
A charge moves along an equipotential surface. Work done is:
Correct Answer: C. zero
Solution: On an equipotential surface, ΔV = 0, so W = qΔV = 0.
Electric field points in the direction of:
Correct Answer: B. decreasing potential
Solution: E = -∇V, so field is opposite to the direction of increasing potential.
Potential inside a charged conducting sphere is:
Correct Answer: C. constant
Solution: Electric field inside conductor is zero, so potential cannot vary with position.
Four equal charges q are placed at the corners of a square side a. Potential at centre is:
Correct Answer: B. 4√2 kq/a
Solution: Distance of each charge from centre is a/√2, so total potential is 4kq/(a/√2).
Charges +q, -q, +q, -q are placed alternately at square corners. Potential at centre is:
Correct Answer: A. zero
Solution: All distances are equal and algebraic sum of charges is zero.
Potential energy of charges q and -2q separated by r is:
Correct Answer: B. -2kq2/r
Solution: Use U = kq1q2/r = k(q)(-2q)/r.
If V = A/r, the electric field magnitude is:
Correct Answer: B. A/r2
Solution: E = -dV/dr = -(-A/r2) = A/r2.
For a short dipole, axial potential varies with distance as:
Correct Answer: B. 1/r2
Solution: Short dipole axial potential is V = kp/r2.
Short dipole potential at angle 90 degrees is:
Correct Answer: C. zero
Solution: V = kp cosθ/r2, and cos 90 degrees is zero.
Adding a constant to potential everywhere changes:
Correct Answer: D. absolute potential values only
Solution: Field and work depend on potential difference or gradient, not absolute reference.
Potential at centre of a uniformly charged ring is:
Correct Answer: A. kQ/R
Solution: Every charge element is at the same distance R, so integrate kdq/R.
Potential on axis of charged ring at distance x is:
Correct Answer: B. kQ/√(R2+x2)
Solution: All ring elements are at distance √(R2 + x2) from the axial point.
If V = 0 at a point, electric field at that point:
Correct Answer: C. may or may not be zero
Solution: Potential is scalar; electric field depends on gradient. Zero potential alone is insufficient.
Electric field at an equipotential surface is:
Correct Answer: B. perpendicular
Solution: Any tangential field would do work along the surface, contradicting ΔV = 0.
Total potential energy of three equal charges q at equilateral triangle side a is:
Correct Answer: C. 3kq2/a
Solution: There are three pairs, each with energy kq2/a.
If V = Ax2, Ex equals:
Correct Answer: B. -2Ax
Solution: Ex = -dV/dx = -2Ax.
For a short dipole, potential is negative when:
Correct Answer: C. cosθ < 0
Solution: V = kp cosθ/r2; sign follows cosθ.
One volt is equal to:
Correct Answer: B. 1 J/C
Solution: V = W/q, so SI unit is joule per coulomb.
If 20 J work is done to move 4 C charge, potential difference is:
Correct Answer: A. 5 V
Solution: ΔV = W/q = 20/4 = 5 V.
Electric potential is a:
Correct Answer: B. scalar
Solution: It is work per unit charge, and both work and charge are scalar.
Potential at distance r from point charge Q is:
Correct Answer: B. kQ/r
Solution: This is the standard point charge potential with zero at infinity.
Electric field inside conductor in electrostatic equilibrium is:
Correct Answer: A. zero
Solution: Charges rearrange until internal field becomes zero.
Potential energy of charge q at potential V is:
Correct Answer: C. qV
Solution: Use U = qV.
Direction of electric dipole moment is:
Correct Answer: B. negative to positive
Solution: By convention, dipole moment points from -q to +q.
Which quantity is energy transferred per unit charge?
Correct Answer: B. Electric potential difference
Solution: Potential difference is work or energy transferred per unit charge.
For an isolated positive point charge, V-r graph is:
Correct Answer: C. positive inverse curve
Solution: V = kQ/r, so it decreases as an inverse curve.
The SI unit V/m is equivalent to:
Correct Answer: B. N/C
Solution: Electric field may be measured in V/m or N/C.
A positive charge moves naturally in the direction of:
Correct Answer: B. decreasing potential
Solution: Positive charges move in the direction of electric field, which points toward decreasing potential.
Why can potential at infinity be chosen as zero?
Correct Answer: B. Because only potential differences matter
Solution: The zero of potential is a reference choice; physical results depend on differences.
At the equatorial point of dipole, V = 0 because:
Correct Answer: C. scalar potentials cancel
Solution: Equal distances and opposite charges make the potential contributions equal and opposite.
If potential at a point is -10 V, potential energy of +2 C charge is:
Correct Answer: A. -20 J
Solution: U = qV = 2 x (-10) = -20 J.
A charge of 3 C moves through 4 V. Energy transferred is:
Correct Answer: B. 12 J
Solution: W = qV = 3 x 4 = 12 J.
Potential difference is measured in:
Correct Answer: A. volt
Solution: The SI unit of potential difference is volt.
Potential difference is energy transferred per:
Correct Answer: C. coulomb
Solution: It is work or energy per unit charge.
If 30 J are transferred by 6 C of charge, p.d. is:
Correct Answer: A. 5 V
Solution: V = W/q = 30/6 = 5 V.
Two points at same potential have potential difference:
Correct Answer: A. zero
Solution: Potential difference is the difference between potentials of two points.
As distance from a positive charge increases, potential:
Correct Answer: B. decreases toward zero
Solution: For a point charge, V = kQ/r.
Potentials +4 V and +7 V combine to give:
Correct Answer: B. 11 V
Solution: Potential is scalar, so add algebraically.
Electric potential due to charge Q at r is:
Correct Answer: B. kQ/r
Solution: The point-charge potential is kQ/r.
A 5 C charge moved through 2 V requires work:
Correct Answer: C. 10 J
Solution: W = qΔV = 5 x 2 = 10 J.
A conductor in electrostatic equilibrium is:
Correct Answer: A. equipotential
Solution: Since E = 0 inside, potential is constant throughout the conductor.
Two like charges have potential energy:
Correct Answer: B. positive
Solution: Product q1q2 is positive for like charges.
Unit of dipole moment is:
Correct Answer: B. C m
Solution: p = charge x distance, so unit is coulomb metre.
If work by external agent per unit charge is 8 J/C, potential difference is:
Correct Answer: A. 8 V
Solution: 1 J/C equals 1 volt.
Equatorial potential of a dipole is:
Correct Answer: A. zero
Solution: The two scalar potentials cancel exactly.
Electric potential equals:
Correct Answer: B. W/q
Solution: It is work done per unit positive test charge.
SI unit of electric potential is:
Correct Answer: A. volt
Solution: The SI unit is volt.
Formula U = qV represents:
Correct Answer: B. potential energy
Solution: Potential energy of charge q at potential V is qV.
Short dipole axial potential is:
Correct Answer: B. kp/r2
Solution: For short dipole on axial line, V = kp/r2.
If n droplets combine, new potential is:
Correct Answer: C. n2/3V
Solution: Use V' = n2/3V.
Relation between E and V in one dimension is:
Correct Answer: B. E = -dV/dr
Solution: Field points in direction of decreasing potential.
Work done on equipotential surface is:
Correct Answer: C. zero
Solution: ΔV = 0 on equipotential surface, so W = qΔV = 0.
Each case study includes a passage and five clickable answer questions in CBSE-style format.
A positive point charge Q is fixed in space. Points A, B and C lie on the same radial line at distances r, 2r and 3r respectively from the charge. Potential at infinity is taken as zero.
Potential at A is proportional to:
Correct Answer: B. 1/r
Solution: For a point charge, V = kQ/r.
Potential at B compared with A is:
Correct Answer: B. half
Solution: At 2r, potential becomes kQ/(2r), which is half.
Potential at C compared with A is:
Correct Answer: A. one-third
Solution: At 3r, potential is one-third of potential at r.
If Q were negative, the potential at A would be:
Correct Answer: B. negative
Solution: Sign of point charge potential follows sign of Q.
Electric field direction for positive Q is:
Correct Answer: A. radially outward
Solution: A positive source charge repels a positive test charge.
An electric dipole consists of charges +q and -q separated by 2a. A point P lies far away at distance r from the centre, making an angle theta with the dipole axis.
Short dipole potential at P is:
Correct Answer: B. kp cosθ/r2
Solution: This is the general short dipole formula.
At theta = 0 degrees, potential is:
Correct Answer: B. kp/r2
Solution: cos 0 degrees = 1.
At theta = 90 degrees, potential is:
Correct Answer: A. zero
Solution: cos 90 degrees = 0.
Dipole moment direction is:
Correct Answer: B. -q to +q
Solution: This is the convention for electric dipole moment.
If r is doubled at same theta, potential becomes:
Correct Answer: B. one-fourth
Solution: Short dipole potential varies as 1/r2.
A charge is moved slowly on a surface where electric potential is constant. The electric field near the surface is not necessarily zero.
Potential difference between two points on the surface is:
Correct Answer: A. zero
Solution: All points on an equipotential surface have the same potential.
Work done in moving charge q on the surface is:
Correct Answer: C. zero
Solution: W = qΔV = 0.
Electric field is directed:
Correct Answer: B. perpendicular to surface
Solution: Tangential electric field would do work along the surface.
Equipotential surfaces for a point charge are:
Correct Answer: B. concentric spheres
Solution: Distance from the point charge is constant on a sphere.
If V is constant, potential gradient along the surface is:
Correct Answer: A. zero
Solution: No change in potential along the surface means zero tangential gradient.
A conducting sphere of radius R carries charge Q and is in electrostatic equilibrium. The potential at infinity is zero.
Potential on surface is:
Correct Answer: A. kQ/R
Solution: A charged conducting sphere behaves like a point charge for outside points and surface value is kQ/R.
Potential at centre is:
Correct Answer: B. kQ/R
Solution: Inside a conductor, potential is constant and equal to surface potential.
Electric field inside is:
Correct Answer: A. zero
Solution: Electrostatic field inside conductor is zero.
Outside at distance 2R, potential is:
Correct Answer: B. kQ/(2R)
Solution: Outside formula is V = kQ/r.
The conductor is:
Correct Answer: B. equipotential
Solution: No internal electric field means no potential gradient inside the conductor.
A large charged drop is formed by combining n identical small droplets. Each small droplet has radius r, charge q and potential V.
Final radius is:
Correct Answer: B. n1/3r
Solution: Volume conservation gives R = n1/3r.
Final charge is:
Correct Answer: B. nq
Solution: Charges add directly.
Final potential is:
Correct Answer: C. n2/3V
Solution: V' = k(nq)/(n1/3r) = n2/3V.
For n = 8, final potential is:
Correct Answer: B. 4V
Solution: 82/3 = 4.
For n = 27, final radius is:
Correct Answer: A. 3r
Solution: 271/3 = 3.
Potential is energy per unit charge; electric field is force per unit charge. Their units, nature and formulas differ.
Do not resolve potential into components. Add signed scalar values directly.
A negative charge creates negative potential when zero is taken at infinity.
For axial exact formula, distances are r - a and r + a from the two charges, not both r.
The equatorial point of a dipole has zero potential but nonzero electric field.
Axial short dipole potential is kp/r2; equatorial potential is zero.
Use V' = n2/3V, not nV, because radius also changes.
Inside a conductor, potential is constant. Do not use V = kQ/r for r < R.
External work for slow motion is qΔV; work by field is -qΔV.
For isolated charges zero at infinity is standard, but potential reference can be shifted by a constant.
Write definitions precisely, show derivation steps for point charge and dipole, and state units. Practice conductor and equipotential explanations in words.
Memorize formulas with sign and distance dependence. Focus on quick MCQs: point charge, dipole equator, droplet factor, conducting sphere and work relation.
Practice mixed numerical problems using superposition, potential energy, potential gradient and conductor graphs. Be careful with algebraic signs.
Strengthen derivations, approximations, continuous charge distributions, field from potential, and multi-charge potential energy.
Emphasize energy transfer per unit charge, graphical interpretation, equipotential reasoning and clear explanations in complete sentences.
Focus on voltage as energy per coulomb, simple work calculations, units, and interpretation of potential difference.
Prepare definitions, properties, point charge formula, conductor potential, and short-answer reasoning about equipotential surfaces.
Practice potential graphs, field as negative gradient, ring potential, and potential energy sign conventions.
Write formula statements cleanly, memorize derivations in sequence, and practice standard numerical examples with units.
Electric potential is work done per unit positive test charge brought from infinity without acceleration.
SI unit is volt. 1 V = 1 J C-1.
V = kQ/r. Sign depends on Q.
Exact: kp/(r2-a2), short dipole: kp/r2.
V = 0 because equal and opposite scalar potentials cancel.
V = kp cosθ/r2 for a short dipole.
External work W = qΔV; field work = -qΔV.
U = qV and U = kq1q2/r.
Inside: constant kQ/R. Outside: kQ/r.
R = n1/3r and V' = n2/3V.
Zero potential does not necessarily mean zero electric field.
Potential adds algebraically; electric field adds vectorially.
Suggested Notes : Electrostatics, Electric Field, Electric Potential Energy, Electric Dipole, Capacitance, Gauss Law, Electric Charges and Fields, CBSE Class 12 Physics, NEET Physics, JEE Physics.
