Some equipotential lines are as shown is fig. `E_(1), E_(2)` and `E_(3)` are the electric fields at points 1, 2, and 3 then -

The figure shows electric field lines. If E_(A) and E_(B) are electric fields at A and B and distance AB is r, then

The figure shows two large, closely parallel, nonconducting sheets with identical (positive) uniform surface charge densities and a sphere with a uniform (positive) volume charge density. Four points marked as 1,2,3 and 4 are shown in the space in between. If E_(1),E_(2),E_(3) and E_(4) are magnitude of net electric fields at these points respectively then :

For the batteries shown in fig. R_1, R_2 and R_3 are the internal resistance of E_1, E_2, and E_3, respectively Then, which of the following is / are correct?

The equation of an equipotential line in an electric field is y = 2 x , then electric field strength vectro at 1, 2 may be .

In an electric field shown in figure, three equipotential figure, three equipotential surfaces are shown. If function are shown. If function of electric field is E=2x^2Vm^(-1) , and given that V_1 - V_2 = V_2-V_3 , then we have

Two coherent sources emit light waves which superimpose at a point where these can be expressed as E_(1) = E_(0) sin(omega t + pi//4) E_(2) = 2E_(0) sin(omega t - pi//4) Here, E_(1) and E_(2) are the electric field strenghts of the two waves at the given point. If I is the intensity of wave expressed by field strenght E_(1) , find the resultant intensity

Two identical dielectric slabs, A and B, are placed symmetrically between the plates X and Y of charged parallel-plate capacitor. The electric intensity has magnitudes E_(1)//E_(2) and E_(3) at the points 1, 2 and 3