The electric field in a region is given by `E = (4 axy sqrt(z))hat i + (2 ax^2 sqrt(z)) hat j + (ax^2 y// sqrt(z)) hat k`
where A is a positive constant. The equation of an equipotential surface will be of the form.

The electric field in a region of space is given by, vec(E ) = E_(0) hat(i) + 2 E_(0) hat(j) where E_(0)= 100N//C . The flux of this field through a circular surface of radius 0.02m parallel to the Y-Z plane is nearly.

The expression (1/(sqrt(2))hat(i)+1/(sqrt(2))hat(j)) is a

The direction cosines of a vector hat(i) + hat(j) + sqrt(2)hat(k) are :

Find the potential function V (x,y) of an electrostatic field vec(E)=2axy hat(i)+a(x^(2)-y^(2))hat(j) where a is a constant.

If vec a=x hat i+2 hat j-z hat k\ and vec b=3 hat i-y hat j+ hat k are two equal vectors, then write the value of x+y+zdot

A non-zero vector vec a is such that its projections along vectors ( hat i+ hat j)/(sqrt(2)),(- hat i+ hat j)/(sqrt(2)) and hat k are equal, then unit vector along vec a is a. (sqrt(2) hat j- hat k)/(sqrt(3)) b. ( hat j-sqrt(2) hat k)/(sqrt(3)) c. (sqrt(2))/(sqrt(3)) hat j+( hat k)/(sqrt(3)) d. ( hat j- hat k)/(sqrt(2))

Angle made by vector sqrt(3)hat(i)+sqrt(2)hat(j)-2hat(k) with -ve y- axis is :

If vec(E)=2x^(2) hat(i)-3y^(2) hat(j) , then V (x, y, z)

If vec a=x hat i+2 hat j-\ z hat k and vec b=3 hat i-\ y hat j+ hat k are two equal vectors, then write the value of x+y+zdot

The electric field in a certain region of space is ( 5 hat(i) 4 hat(j) - 4 hat(k)) xx 10^(5) [ N //C] . Calculate electric flux due to this field over an area of ( 2 hat(i) - hat(j)) xx 10^(-2) [ m^(2)]