A Gaussian sphere encloses an electric dipole within it. The total flux across the sphere is
zero
half that due to a single charge
double that due to a single charge
dependent on the position of the dipole
The specific charge of a proton is 9.6 x107 C kg-1 The specific charge of an alpha particle will be
9.6 x107 C kg-1
19.2 x107 C kg-1
4.8 x107 C kg-1
2.4 x107 C kg-1
Point charges + 4q, - q and+ 4q are kept on the x-axis at points x = 0, x = a and x = 2a respectively, then
only- q is in stable equilibrium
all the charges are in stable equilibrium
all the charges are in unstable equilibrium
none of the above
If Ea be the electric field strength of a short dipole at a point on its axial line and Ee that on equilateral line at the same distance, then
Ee = 2Ea
Ea = 2Ee
Ea = Ee
none of these
Charges 4Q, q and Q are placed along x-axis at positions x = 0, x = l/2 and x = l, respectively. Find the value of q so that the force on charge Q is zero:
Q
-Q
Two small charged spheres A and B have charges 10 C and 40 C respectively and are held at a separation of 90 cm from each other. At what distance from A, the electric intensity would be zero?
22.5 cm
18 cm
36 cm
30 cm
D.
30 cm
Let at point D intensity, is zero
90 - x = 2x
3x = 90
x = 30 cm
A charged particle moves in an electric field from A to B, then from B to A :
If WAB > WBA, then the field is conservative
If WAB + WBA = 0, then the field is conservative
If WAB + WBA > 0, then the field is conservative
If WAB = WBA, then the field is conservative
What is the angle between the electric dipole moment and the electric field strength due to it on the equatorial line?
0°
90°
180°
None of these
Two spheres of radii R1 and R2 respectively are charged and joined by a wire. The ratio of the electric field of spheres is :
The figure shows three points A, B and C in a region of a uniform electric field . The line AB is perpendicular and BC is parallel to the field lines. Then which of the following holds good?
VA = VB = VC
VA = VB > VC
VA = VB < VC
VA > VB = VC