267793
The electric field at a point at a distance \(r\) from an electric dipole is proportional to
1 \(\frac{1}{r}\)
2 \(\frac{1}{r^{2}}\)
3 \(\frac{1}{r^{3}}\)
4 \(r^{2}\)
Explanation:
Electric Charges and Fields
267794
An electric dipole placed with its axis in the direction of a uniform electric field experiences
1 aforcebut not torque
2 a torquebut no force
3 a force as well as a torque
4 neither a force nor a torque
Explanation:
Electric Charges and Fields
267819
**Assertion(A):** E lectric potential at any point on the equatorial line of electric dipole is zero.
**Reason (R):** Electric potential is scalar
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267820
**Assertion(A):** The potential at any point due to a group of ' \(N\) ' point charges is simply arrived at by the principle of superposition
**Reason ( \(R\) ):** The potential energy of a system of two charges is a scalar quantity
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267821
**Assertion (A):** The electrostatic potential energy is independent of the manner in which the cofiguration is achieved
**Reason (R):** Electrostatic field is conservative field
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
267793
The electric field at a point at a distance \(r\) from an electric dipole is proportional to
1 \(\frac{1}{r}\)
2 \(\frac{1}{r^{2}}\)
3 \(\frac{1}{r^{3}}\)
4 \(r^{2}\)
Explanation:
Electric Charges and Fields
267794
An electric dipole placed with its axis in the direction of a uniform electric field experiences
1 aforcebut not torque
2 a torquebut no force
3 a force as well as a torque
4 neither a force nor a torque
Explanation:
Electric Charges and Fields
267819
**Assertion(A):** E lectric potential at any point on the equatorial line of electric dipole is zero.
**Reason (R):** Electric potential is scalar
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267820
**Assertion(A):** The potential at any point due to a group of ' \(N\) ' point charges is simply arrived at by the principle of superposition
**Reason ( \(R\) ):** The potential energy of a system of two charges is a scalar quantity
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267821
**Assertion (A):** The electrostatic potential energy is independent of the manner in which the cofiguration is achieved
**Reason (R):** Electrostatic field is conservative field
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
267793
The electric field at a point at a distance \(r\) from an electric dipole is proportional to
1 \(\frac{1}{r}\)
2 \(\frac{1}{r^{2}}\)
3 \(\frac{1}{r^{3}}\)
4 \(r^{2}\)
Explanation:
Electric Charges and Fields
267794
An electric dipole placed with its axis in the direction of a uniform electric field experiences
1 aforcebut not torque
2 a torquebut no force
3 a force as well as a torque
4 neither a force nor a torque
Explanation:
Electric Charges and Fields
267819
**Assertion(A):** E lectric potential at any point on the equatorial line of electric dipole is zero.
**Reason (R):** Electric potential is scalar
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267820
**Assertion(A):** The potential at any point due to a group of ' \(N\) ' point charges is simply arrived at by the principle of superposition
**Reason ( \(R\) ):** The potential energy of a system of two charges is a scalar quantity
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267821
**Assertion (A):** The electrostatic potential energy is independent of the manner in which the cofiguration is achieved
**Reason (R):** Electrostatic field is conservative field
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
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Electric Charges and Fields
267793
The electric field at a point at a distance \(r\) from an electric dipole is proportional to
1 \(\frac{1}{r}\)
2 \(\frac{1}{r^{2}}\)
3 \(\frac{1}{r^{3}}\)
4 \(r^{2}\)
Explanation:
Electric Charges and Fields
267794
An electric dipole placed with its axis in the direction of a uniform electric field experiences
1 aforcebut not torque
2 a torquebut no force
3 a force as well as a torque
4 neither a force nor a torque
Explanation:
Electric Charges and Fields
267819
**Assertion(A):** E lectric potential at any point on the equatorial line of electric dipole is zero.
**Reason (R):** Electric potential is scalar
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267820
**Assertion(A):** The potential at any point due to a group of ' \(N\) ' point charges is simply arrived at by the principle of superposition
**Reason ( \(R\) ):** The potential energy of a system of two charges is a scalar quantity
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267821
**Assertion (A):** The electrostatic potential energy is independent of the manner in which the cofiguration is achieved
**Reason (R):** Electrostatic field is conservative field
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
267793
The electric field at a point at a distance \(r\) from an electric dipole is proportional to
1 \(\frac{1}{r}\)
2 \(\frac{1}{r^{2}}\)
3 \(\frac{1}{r^{3}}\)
4 \(r^{2}\)
Explanation:
Electric Charges and Fields
267794
An electric dipole placed with its axis in the direction of a uniform electric field experiences
1 aforcebut not torque
2 a torquebut no force
3 a force as well as a torque
4 neither a force nor a torque
Explanation:
Electric Charges and Fields
267819
**Assertion(A):** E lectric potential at any point on the equatorial line of electric dipole is zero.
**Reason (R):** Electric potential is scalar
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267820
**Assertion(A):** The potential at any point due to a group of ' \(N\) ' point charges is simply arrived at by the principle of superposition
**Reason ( \(R\) ):** The potential energy of a system of two charges is a scalar quantity
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '
3 'A' is true and 'R' is false
4 'A' is false and 'R' is true
Explanation:
Electric Charges and Fields
267821
**Assertion (A):** The electrostatic potential energy is independent of the manner in which the cofiguration is achieved
**Reason (R):** Electrostatic field is conservative field
1 Both 'A' and 'R' are true and 'R' is the correct explanation of ' \(A\) '
2 Both 'A' and 'R' are true and 'R' is not the correct explanation of ' \(A\) '