The cube in figure has edge length `sqrt2m` and is oriented as shown in a region of uniform electric field , in newtons per coulomb, is given by `(a)6.00hati , (b) -2.00 hatj, and (c) -3.00 hatj+ 4.00 hatk` . (d) what is the total flux through the cube for each field ?

A cube of edge length l = 2.50 cm is positioned as shown in Fig. 3.20. A uniform magnetic field given by vec(B) = (5.00 hat(i) + 4.00hat(j) + 3.00hat(k)) T exists throughout the region. (a) Calculate the flux through the shaded face. (b) What is the total flux through the six faces ?

A cube has sides of length L = 0.2 m. It is placed with one corner at the origin as shown in figure. The electric field is uniform and given by E= (2.5 N//C) hati - (4.2 N//C) hatj . Find the electric flux through the entire cube.

A cube has sides of length L. It is placed with one corner at the origin as shown in figure. The electric field is uniform and given by E = - B hati + Chatj - Dhatk , where B, C and D are positive constants. (a) Find the electric flux through each of the six cube faces S_1, S_2, S_3 , S_4 and S_5 and S_6 . (b) Find the electric flux through the entire cube.

A cube has sides of length L = 0.300 m . It is placed with one corner at the origin ( refer to Fig.2.119).The electric field is not uniform but is given by vec( E) = ( -5.00 NC^(-1)) x hat(i) + (3.00 NC^(-1)) z hat(k) . The total electric charge inside the cube is

A cube has sides of length L . It is placed with one corner at the origin ( refer to Fig.2.119). The electric field is uniform and given by vec€ = - B hat (i) + C hat (j) - D hat(k) , where B , C , and D are positive constants. The total flux passing through the cube is

A cube has sides of length L = 0.300 m . It is placed with one corner at the origin ( refer to Fig.2.119).The electric field is not uniform but is given by vec( E) = ( -5.00 NC^(-1)) x hat(i) + (3.00 NC^(-1)) z hat(k) . The flux passing through the surface S_(5) will be

An electric field given vecE= 4.0hati -3.0(y^(2) + 2.0)j pierces a Gaussian cube of edge length 2.0 m and positioned as shown in the figure. (The magnitude E is in newtons per coulomb and the position z is in meters.) what is the electric flux through the (a) top face, (b) bottom face, (c) left face , (b) bottom facem (c) left face, and (d) back face ? (e) what is the net electric flux through the cube ?

the figure shows the path of A positively charged particle through a rectangular region of uniform electric field as shown in the figure. the direction of deflection of particle 2, 3 and 4 is

Electric field in a region is uniform and is given by vec(E)-a hati+b hatj+c hatk . Electric flux associated with a surface of area vec(A)=pi R^(2)hati is

(A)Two point charges q_1 and q_2 are kept r distance apart in a uniform external electric field vecE . Find the amount of work done in assembling this system of charges. (B) A cube of side 20 cm is kept in a region as shown in the figure. An electric field vecE exists in the region such that the potential at a point is given by V = 10x + 5 , where V is in volt and x is in m. Find the electric field vecE and (ii) total electric flux through the cube.