267748
Intensity of electric field inside a uniformly charged hollow sphere is
1 zero
2 nonzero constant
3 change with \(r\)
4 inversely proportional to \(r\)
Explanation:
Electric Charges and Fields
267749
A positive charge \(q_{0}\) placed at a point \(P\) near a charged body experiences a force of repulsion of magnitude \(F\), the electric field \(E\) of the charged body at \(P\) is
1 \(\frac{F}{q_{0}}\)
2 \(\lt \frac{F}{q_{0}}\)
3 \(>\frac{F}{q_{0}}\)
4 \(F\)
Explanation:
Electric Charges and Fields
267750
A cube of side \(b\) has charge \(q\) at each of its vertices. The electric field at the centre of the cube will be (K AR NATAK A CET 2000)
1 zero
2 \(\frac{32 q}{b^{2}}\)
3 \(\frac{q}{2 b^{2}}\)
4 \(\frac{q}{b^{2}}\)
Explanation:
Electric Charges and Fields
267751
An electron and proton are sent into an electric field. The ratio of force experienced by them is
1 \(1: 1\)
2 \(1: 1840\)
3 \(1840: 1\)
4 \(1: 9.11\)
Explanation:
Electric Charges and Fields
267752
An electron enters an electric field with its velocity in the direction of the electric lines of force. Then
267748
Intensity of electric field inside a uniformly charged hollow sphere is
1 zero
2 nonzero constant
3 change with \(r\)
4 inversely proportional to \(r\)
Explanation:
Electric Charges and Fields
267749
A positive charge \(q_{0}\) placed at a point \(P\) near a charged body experiences a force of repulsion of magnitude \(F\), the electric field \(E\) of the charged body at \(P\) is
1 \(\frac{F}{q_{0}}\)
2 \(\lt \frac{F}{q_{0}}\)
3 \(>\frac{F}{q_{0}}\)
4 \(F\)
Explanation:
Electric Charges and Fields
267750
A cube of side \(b\) has charge \(q\) at each of its vertices. The electric field at the centre of the cube will be (K AR NATAK A CET 2000)
1 zero
2 \(\frac{32 q}{b^{2}}\)
3 \(\frac{q}{2 b^{2}}\)
4 \(\frac{q}{b^{2}}\)
Explanation:
Electric Charges and Fields
267751
An electron and proton are sent into an electric field. The ratio of force experienced by them is
1 \(1: 1\)
2 \(1: 1840\)
3 \(1840: 1\)
4 \(1: 9.11\)
Explanation:
Electric Charges and Fields
267752
An electron enters an electric field with its velocity in the direction of the electric lines of force. Then
267748
Intensity of electric field inside a uniformly charged hollow sphere is
1 zero
2 nonzero constant
3 change with \(r\)
4 inversely proportional to \(r\)
Explanation:
Electric Charges and Fields
267749
A positive charge \(q_{0}\) placed at a point \(P\) near a charged body experiences a force of repulsion of magnitude \(F\), the electric field \(E\) of the charged body at \(P\) is
1 \(\frac{F}{q_{0}}\)
2 \(\lt \frac{F}{q_{0}}\)
3 \(>\frac{F}{q_{0}}\)
4 \(F\)
Explanation:
Electric Charges and Fields
267750
A cube of side \(b\) has charge \(q\) at each of its vertices. The electric field at the centre of the cube will be (K AR NATAK A CET 2000)
1 zero
2 \(\frac{32 q}{b^{2}}\)
3 \(\frac{q}{2 b^{2}}\)
4 \(\frac{q}{b^{2}}\)
Explanation:
Electric Charges and Fields
267751
An electron and proton are sent into an electric field. The ratio of force experienced by them is
1 \(1: 1\)
2 \(1: 1840\)
3 \(1840: 1\)
4 \(1: 9.11\)
Explanation:
Electric Charges and Fields
267752
An electron enters an electric field with its velocity in the direction of the electric lines of force. Then
267748
Intensity of electric field inside a uniformly charged hollow sphere is
1 zero
2 nonzero constant
3 change with \(r\)
4 inversely proportional to \(r\)
Explanation:
Electric Charges and Fields
267749
A positive charge \(q_{0}\) placed at a point \(P\) near a charged body experiences a force of repulsion of magnitude \(F\), the electric field \(E\) of the charged body at \(P\) is
1 \(\frac{F}{q_{0}}\)
2 \(\lt \frac{F}{q_{0}}\)
3 \(>\frac{F}{q_{0}}\)
4 \(F\)
Explanation:
Electric Charges and Fields
267750
A cube of side \(b\) has charge \(q\) at each of its vertices. The electric field at the centre of the cube will be (K AR NATAK A CET 2000)
1 zero
2 \(\frac{32 q}{b^{2}}\)
3 \(\frac{q}{2 b^{2}}\)
4 \(\frac{q}{b^{2}}\)
Explanation:
Electric Charges and Fields
267751
An electron and proton are sent into an electric field. The ratio of force experienced by them is
1 \(1: 1\)
2 \(1: 1840\)
3 \(1840: 1\)
4 \(1: 9.11\)
Explanation:
Electric Charges and Fields
267752
An electron enters an electric field with its velocity in the direction of the electric lines of force. Then
267748
Intensity of electric field inside a uniformly charged hollow sphere is
1 zero
2 nonzero constant
3 change with \(r\)
4 inversely proportional to \(r\)
Explanation:
Electric Charges and Fields
267749
A positive charge \(q_{0}\) placed at a point \(P\) near a charged body experiences a force of repulsion of magnitude \(F\), the electric field \(E\) of the charged body at \(P\) is
1 \(\frac{F}{q_{0}}\)
2 \(\lt \frac{F}{q_{0}}\)
3 \(>\frac{F}{q_{0}}\)
4 \(F\)
Explanation:
Electric Charges and Fields
267750
A cube of side \(b\) has charge \(q\) at each of its vertices. The electric field at the centre of the cube will be (K AR NATAK A CET 2000)
1 zero
2 \(\frac{32 q}{b^{2}}\)
3 \(\frac{q}{2 b^{2}}\)
4 \(\frac{q}{b^{2}}\)
Explanation:
Electric Charges and Fields
267751
An electron and proton are sent into an electric field. The ratio of force experienced by them is
1 \(1: 1\)
2 \(1: 1840\)
3 \(1840: 1\)
4 \(1: 9.11\)
Explanation:
Electric Charges and Fields
267752
An electron enters an electric field with its velocity in the direction of the electric lines of force. Then
