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

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 magnetic field vec(B) = B_(0)hat(j) , exists in the region a ltxlt2a , and vec(B) = -B_(0) hat(j) , in the region 2a lt xlt 3a , where B_(0) is a positive constant . A positive point charge moving with a velocity vec(v) = v_(0) hat (i) , where v_(0) is a positive constant , enters the magnetic field at x= a . The trajectory of the charge in this region can be like

In a certain region static electric and magentic fields exist. The magnetic field is given by vec(B) = B_(0) (hat(i) + 2hat(j)-4hat(k)) . If a test charge moving with a velocity, vec(upsilon) = upsilon_(0)(3hat(i)-hat(j) +2hat(k)) experience no force in that region, then the electric field in the region, in SI units, is-

In a certain region static electric and magentic fields exist. The magnetic field is given by vec(B) = B_(0) (hat(i) + 2hat(j)-4hat(k)) . If a test charge moving with a velocity, vec(upsilon) = upsilon_(0)(3hat(i)-hat(j) +2hat(k)) experience no force in that region, then the electric field in the region, in SI units, is-

A particle of charge q and mass m starts moving from the origin under the action of an electric field vec E = E_0 hat i and vec B = B_0 hat i with a velocity vec v = v_0 hat j . The speed of the particle will become 2v_0 after a time.

A particle of charge q and mass m starts moving from the origin under the action of an electric field vec E = E_0 hat i and vec B = B_0 hat i with a velocity vec v = v_0 hat j . The speed of the particle will become 2v_0 after a time.

A particle of charge q and mass m starts moving from the origin under the action of an electric field vec E = E_0 hat i and vec B = B_0 hat i with a velocity vec v = v_0 hat j . The speed of the particle will become 2v_0 after a time.

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

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

A charged particle with charge to mass ratio ((q)/(m)) = (10)^(3)/(19) Ckg^(-1) enters a uniform magnetic field vec(B) = 20 hat(i) + 30 hat(j) + 50 hat(k) T at time t = 0 with velocity vec(V) = (20 hat(i) + 50 hat(j) + 30 hat(k)) m//s . Assume that magnetic field exists in large space. During the further motion of the particle in the magnetic field, the angle between the magnetic field and velocity of the particle