What would happen to the electric field inside an insulator if placed in the electric field between two parallel bars in the experiment
nothing |
||
gets stronger |
||
gets weaker |
||
is zero |
||
none of these |
What is the strength of electric field along an equipotential line?
zero |
||
Maximum |
||
Depends on the actual potential |
||
changes direction |
||
none of these |
What is the strength of the electric field inside the metal ring placed in the electric field?
Depends on the potential of the ring |
||
Depends on the location of the ring |
||
Depends on the potential difference applied to the conductors that generate the field |
||
There is no way to tell |
||
none of these |
How does a chargeless piece of styrofoam initially interacts with a charged rod?
gets replled |
||
gets attracted |
||
Depends on the polarity of the charge |
||
does not interact |
||
none of these |
"As you move from the bar connected to the negative terminal of the power supply towards the opposite bar, the strength of the electric field"
increases |
||
decreases |
||
it is always zero |
||
remains constant |
||
none of these |
Please pick one of the options for each question
1.Gets weaker
As the induced is along opposite direction.
2.Zero
By defination of electric field , electric field is potential gradient but here potential is constant so Electric field is zero.
3.Depends on the potential difference applied to the conductors that generate the field.
All other options are wrong.
4.gets attracted
By charging by induction , opposite charge is induced.
5.Increases
As potential is same and distance is decreasing
What would happen to the electric field inside an insulator if placed in the electric field...
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