Two infinitely long parallel wires having linear charge densities `lambda_(1)` and `lambda_(2)` respectively are placed at a distance of `R` metres. The force per unit length on either wire will be `(k= 1/(4piepsilon_(0)))`

When two parallel wires carrying current l and 2l in same direction are placed at a distance d apart, the ratio of force per unit length acting upon the wire due to other is

Two parallel infinite line charges with linear charge densities +lambda C//m and -lambda C/m are placed at a distance of 2R in free space. What is the electric field mid-way between the two line charges?

Two parallel infinite line charges with linear charge densities +lambda C//m and -lambda C/m are placed at a distance of 2R in free space. What is the electric field mid-way between the two line charges?

Two infinitely long thin straight wires having uniform linear charge densities lambda and 2lambda are arranged parallel to each other at a distance r apart.The intensity of the electric field at a point midway between them is

Two uniformly long charged wires with linear densities lambda and 3lambda are placed along X and Y axis respectively. Determined the slope of electric field at any point on the l ine y=sqrt3x

Two long parallel copper wires carry current of 5A each in opposite directions. If the wires are separated by a distance distance of 0.5m, then the force per unit length between the two wires is

Between two infinitely long wires having linear charge densities lambda and - lambda , there are two points A and B as shown in the figure. The amount of work done by the electric field in moving a point charge q_(0) from A to B is equal to :

Two mutually perpendicular long straight conductors carrying uniformly distributed charges of linear charges densities lambda_(1) and lambda_(2) are positon at a distance a from each other. How does the interaction between the rods depends on a ?

An infinitely long wire with linear charge density +lambda is bent and the two parts are inclined at angle 30^@ as shown in fig, the electric field at point P is :

An infinitely long string uniformly charged with a linear charge density lambda_(1) and a segment of length l uniformly charge with linear charge density lambda_(2) lie in a plane at right angles to each other and separated by a distance r_(0) as shown in figure. The force with which these two interact is (lambda_(1) lambda_(2))/(4 pi epsi_(0)) ln (x) . If l=r_(0) , then find the value of x.