The electric potential V ( in volt) varies with x ( in meter) a according to the reltion ` V = 15 + 4x^(2)` . The force experience by a negative charge of 2 c located at x= 5 m is n N. Find n.

The electric potential (V) in volts varies with x (in metre) according to the relation V = 5 + 4x^(2) . The force experienced by a negative charge of 2 mu C located at x = 0.5 m is

The electric potetnial in a region along x-axis varies with x according to the releation V(x) = 4 xx 5x^(2) . Then the incorrect statement is

Electric potential in a region is varying according to the relation V = (3x^(2))/(2) - (y^(2))/(4) , where x and y are in metre and V is volt, Electric field intensity (in N/C) at a point (1 m, 2 m ) is

The electric potential V at any point x, y, z (all in meters) in space is given by V=4x^2 volts. The electric field at the point (1m, 0, 2m) is…………….. V//m .

The electric potential V at any point (x,y,z) , all in meters in space is given by V= 4x^(2) volt. The electric field at the point (1,0,2) in volt//meter is

The electric potential V at any point x,y,z (all in metre) in space is given by V=4x^2 volt. The electric field at the point (1m, 0, 2m) is …………… V/m .

The electric potential V is givne as a function of distance x (metre) by V = (5 x^(2) + 10x - 9) volt. Value of electric field at x = 1 is

The electric potential V is givne as a function of distance x (metre) by V = (5 x^(2) + 10x - 9) volt. Value of electric field at x = 1 is

The potential V is varying with x as V = (1)/(2) (y^2 - 4 x) volt. The field at x = 1m, y = 1 m, is.

We know that electric field (E ) at any point in space can be calculated using the relation vecE = - (deltaV)/(deltax)hati - (deltaV)/(deltay)hatj - (deltaV)/(deltaz)hatk if we know the variation of potential (V) at that point. Now let the electric potential in volt along the x-axis vary as V = 2x^2 , where x is in meter. Its variation is as shown in figure A charge particle of mass 10 mg and charge 2.5 muC is released from rest at x = 2 m . Find its velocity when it crosses origin.