In any region, if electric field is define as `bar(E ) = ( hat(i) + 2 hat(j)+ hat(k))V//m` , then the potential differnece between two points `A ( 0,0,0)` and `B ( 2,3,4)` in that region is

An electric field is described as vec(E) = hat(i)x + hat(k) z . The potential difference V_(AB) (in volt) between A(0,0,0) and B(2,2,0) is :

An electric field is expressed as vec(E) = 2hat(i) + 3hat(j) . Find the potential difference (V_(A) - V_(B)) between two point A and B whose position vectors are give by vec(r_(A)) = hat(i) + 2j and vec(r_(B)) = 2hat(i) + hat(j) + 3hat(k)

An electric field is expressed as vec E = 2 hat i + 3 hat j . Find the potential difference (V_A - V_B) between two points A and B whose position vectors are given by r_A = hat i + 2 hat j and r_B = 2 hat i + hat j + 3 hat k .

The electric field in a certain region is given by E=5 hat(i)-3hat(j) kv//m . The potential difference V_(B)-V_(A) between points a and B having coordinates (4, 0, 3) m and (10, 3, 0) m respectively, is equal to

An electric field is expresed as vec(E)=2hat(i)+3hat(j) The potential difference (V_(A)-V_(B)) between two given by r_(A)=hat(i)+2hat(j) and r_(B)=2hat(i)+hat(j)+3hat(k) 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-

The displacement of a charge Q in the electric field vec(E) = e_(1)hat(i) + e_(2)hat(j) + e_(3) hat(k) is vec(r) = a hat(i) + b hat(j) . The work done is

If bar(a) = 4 hat(i) + 3 hat(k) and bar(b) = - 2 hat(i) + hat(j) + 5 hat(k) then find 2 bar(a) + 5 bar(b)

A particle having mass m and charge q is released from the origin in a region in which electric field and megnetic field are given by vec(B) = -B_(0)hat(j) and vec(E) = vec(E)_(0)hat(k) . Find the speed of the particle as a function of its z -coordinate.