The electric field in a region of space has the components `E_(y) = E_(z) =0 and E_(x)= (4.00 N//C)x^(2)`. Point A is on the y axis at y = 3.00 m, and point B is on the x axis at x = 4.00 m. What is the potential difference `V_(B) - V_(A)` ?

The electric field in a region of space is given as bar(E)=(5xhat i-2hat j) .Potential at point x =1 y =1 is V_(1) and potential at point x =2 y =3 is V_(2) .Then V_(1)-V_(2) is equal to

The electric field in a region of space is given as bar(E)=(5xhat i-2hat j) .Potential at point x=1 y=1 is V_(1) and potential at point (x=2 y=3) is V_(2) .Then V_(1) -V_(2) is equal to

A uniform electric field of 400 V/m is directed at 45^@ above the x-axis as shown in the figure. The potential difference V_A-V_B is given by

Electric potential in a region of space is given by V=(x^(2)+y^(2)+z^(2))V . What will be electric field intensity at a point P(-1m, 2m, -3m)?

A positively charged particle, having charge q, is accelerated by a potential difference V. This particle moving along the x-axis enters a region where an electric field E exists. The direction of the electric field is along positive y-axis. The electric field exists in the region bounded by the lines x=0 and x=a. Beyond the line x=a (i.e., in the region xgta ), there exists a magnetic field of strength B, directed along the positive y-axis. Find a. at which point does the particle meet the line x=a . b. the pitch of the helix formed after the particle enters the region xgea. (Mass of the particle is m.)

In a certain region, electric field E exists along the x - axis which is uniform. Given B = 2 sqrt(3) m and BC = 4 m . Points A, B, and C are in x y plane. . find the potential difference V_C - V_B between the points C and B .

In a certain region, electric field E exists along the x - axis which is uniform. Given B = 2 sqrt(3) m and BC = 4 m . Points A, B, and C are in x y plane. . Find the potential difference V_A - V_B between the points A and B .

A graph of the x-component of the electric field as a function of x in a region of space is shown in figure. The y- and z-components of the electric field are zero in this region. If the electric potential is 10 V at the origin, then the potential at x = 2.0 m is

The electric potential in aregion of space is given by V=(5x-7x^(2)y+8y^(2)+16yz-4z) volt. The y-component of the electric field at the point (2,4,-3) is