In a region of space uniform electric field is present as `vec(E)=E_(0)hat(i)` and uniform magnetci field is present as `vec(B)=-B_(0)hat(j)` . An electron is released from rest at origin. What is the path followed by electron after released. `(E_(0) & B_(0)`are positive constants )

In a region of space uniform electric field is present as vec(E)=E_(0)hat(j) and uniform magnetci field is present as vec(B)=B_(0)hat(j) . An electron is released from rest at origin. Which of the following best represent the path followed by electron after released. (E_(0) & B_(0) are positive constants )

Electric field strength bar(E)=E_(0)hat(i) and magnetic induction bar(B)=B_(0)hat(i) exists in a region. A charged particle 'q' is released from rest at origin. Work done by both the fields is after certain time is

An electron is projected wit velocity vec(v) = v_(0) hat(x) in an electric field vec(E) = E_(0) hat(y) . Trace the path followed by the electron :-

A portion is fired from origin with velocity vec(v) = v_(0) hat(j)+ v_(0) hat(k) in a uniform magnetic field vec(B) = B_(0) hat(j) . In the subsequent motion of the proton

In a region, steady and uniform electric and magnetic fields are present . These two fields are parallel to each other. A charged particle is released from rest in this region . The path of the particle will be a

The potential field of an electric field vec(E)=(y hat(i)+x hat(j)) is

Electric field strength bar(E)=E_(0)hat(i) and bar(B)=B_(0)hat(i) exists in a region. A charge is projected with a velocity bar(v)=v_(0)hat(j) at origin , then

In a region of space , suppose there exists a uniform electric field vec(E ) = 10 hat(i) ( V /m) . If a positive charge moves with a velocity vec(v ) = -2 hat(j) , its potential energy

A rectangular loop of dimensions (axxb) carries a current i. A uniform magnetic field vec(B)=B_(0) hat(i) exists in space. Then :