267798
The electric potential due to an extremely short dipole at a distance \(r\) from it is proportional to
1 \(\frac{1}{r}\)
2 \(\frac{1}{r^{2}}\)
3 \(\frac{1}{r^{3}}\)
4 \(\frac{1}{r^{4}}\)
Explanation:
Electric Charges and Fields
267799
An electric dipole when placed in a uniform electric field will have minimum potential energy, if the angle between dipole moment and electric field is
1 zero
2 \(\pi / 2\)
3 \(\pi\)
4 \(3 \pi / 2\)
Explanation:
Electric Charges and Fields
267800
The angle between the electric dipole moment and the electric field strength due to it, on the equatorial line is
1 \(0^{\circ}\)
2 \(90^{\circ}\)
3 \(180^{\circ}\)
4 \(60^{\circ}\)
Explanation:
Electric Charges and Fields
267801
A metallic shell has a point charge \(q\) kept inside its cavity. Which one of the following diagrams correctly represents the electric lines of forces?
267798
The electric potential due to an extremely short dipole at a distance \(r\) from it is proportional to
1 \(\frac{1}{r}\)
2 \(\frac{1}{r^{2}}\)
3 \(\frac{1}{r^{3}}\)
4 \(\frac{1}{r^{4}}\)
Explanation:
Electric Charges and Fields
267799
An electric dipole when placed in a uniform electric field will have minimum potential energy, if the angle between dipole moment and electric field is
1 zero
2 \(\pi / 2\)
3 \(\pi\)
4 \(3 \pi / 2\)
Explanation:
Electric Charges and Fields
267800
The angle between the electric dipole moment and the electric field strength due to it, on the equatorial line is
1 \(0^{\circ}\)
2 \(90^{\circ}\)
3 \(180^{\circ}\)
4 \(60^{\circ}\)
Explanation:
Electric Charges and Fields
267801
A metallic shell has a point charge \(q\) kept inside its cavity. Which one of the following diagrams correctly represents the electric lines of forces?
267798
The electric potential due to an extremely short dipole at a distance \(r\) from it is proportional to
1 \(\frac{1}{r}\)
2 \(\frac{1}{r^{2}}\)
3 \(\frac{1}{r^{3}}\)
4 \(\frac{1}{r^{4}}\)
Explanation:
Electric Charges and Fields
267799
An electric dipole when placed in a uniform electric field will have minimum potential energy, if the angle between dipole moment and electric field is
1 zero
2 \(\pi / 2\)
3 \(\pi\)
4 \(3 \pi / 2\)
Explanation:
Electric Charges and Fields
267800
The angle between the electric dipole moment and the electric field strength due to it, on the equatorial line is
1 \(0^{\circ}\)
2 \(90^{\circ}\)
3 \(180^{\circ}\)
4 \(60^{\circ}\)
Explanation:
Electric Charges and Fields
267801
A metallic shell has a point charge \(q\) kept inside its cavity. Which one of the following diagrams correctly represents the electric lines of forces?
NEET Test Series from KOTA - 10 Papers In MS WORD
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Electric Charges and Fields
267798
The electric potential due to an extremely short dipole at a distance \(r\) from it is proportional to
1 \(\frac{1}{r}\)
2 \(\frac{1}{r^{2}}\)
3 \(\frac{1}{r^{3}}\)
4 \(\frac{1}{r^{4}}\)
Explanation:
Electric Charges and Fields
267799
An electric dipole when placed in a uniform electric field will have minimum potential energy, if the angle between dipole moment and electric field is
1 zero
2 \(\pi / 2\)
3 \(\pi\)
4 \(3 \pi / 2\)
Explanation:
Electric Charges and Fields
267800
The angle between the electric dipole moment and the electric field strength due to it, on the equatorial line is
1 \(0^{\circ}\)
2 \(90^{\circ}\)
3 \(180^{\circ}\)
4 \(60^{\circ}\)
Explanation:
Electric Charges and Fields
267801
A metallic shell has a point charge \(q\) kept inside its cavity. Which one of the following diagrams correctly represents the electric lines of forces?
