A finite line of positive charge(with linear density lambda) is centered at the origin along on...
A line of charge along the y-axis has linear charge density +lambda from y = 0 to y= +a, and -lambda from y=0 to y=-a. I want to find an expression for the electric field at any point x along the x-axis It is noted that the charge configuration is similar in structure to a dipole. By symmetry, the x-components of the field cancel out, and the net field is in the y-direction. Here a = 1.5 m, lambda =...
30 An infinite line of charge with linear density λ,--S6pcim is positioned along the axis of a thick conducting shell of inner radius a 3.4 cm and outer radius b-54 cm and infinite length. The conducting shell is uniformly charged with a linear charge density A 2 3.5 uC/m 1) What is EXP), the electric field at point P, located at (x,y)卟7.6cm, 0cm) ? NIC Submit 2) What is Ey/P), the electric field at point P, located at (xy)-(-7.6 cm,...
30 Line 1 An infinite line of charge with linear density 6.4pC/m is positioned along the axis of a thick conducting shell of inner radius a . 2.8 cm and outer radius b-4.6 cm and infinite length. The conducting shell is uniformly charged with a linear charge density A 2-4.4 HC/m 1) What is E(P), the electric field at point P, located at (x,y) (-10.6 cm, 0 cm)? N/C Submit 2) What is EyIP), the electric field at point P,...
8. Positive charge is distributed along a very thin wire of length L, centered at the origin of an x-axis. The linear density obeys the following relationship, u(x)-olr, where 14, and β are constants (a) Derive an expression for the electric field vector on the y-axis generated by this charge distribution. (b) How does this expression change, if the wire is infinitely extended? How does the expression derived at (a) change, if β-0, and what does β-O mean physically? (c)...
An infinite line charge of uniform linear charge density lambda = -3.7 mu or micro CC/m lies parallel to the y axis at x = -2 m. A point charge of 1.1 mu or micro CC is located at x = 1.0 m, y = 2.0 m. Find the x component of the electric field at x = 2.0 m, y = 1.5 m.
An infinite line charge of uniform linear charge density lambda = -1.1 mu or micro CC/m lies parallel to the y axis at x = -2 m. A point charge of 4.7 mu or micro CC is located at x = 2.0 m, y = 3.0 m. Find the x component of the electric field at x = 3.0 m, y = 2.5 m.
An infinite line charge of uniform linear charge density lambda = -1.1 mu or micro CC/m lies parallel to the y axis at x = -2 m. A point charge of 4.7 mu or micro CC is located at x = 2.0 m, y = 3.0 m. Find the x component of the electric field at x = 3.0 m, y = 2.5 m.
The figure below shows a finite line charge with linear charge
density of λ and total length L. The point P shown is a distance s
away from its end.
Please calculate a formula for the electric field at point P, in
terms of λ, L and s.
Then use the following values to find it
numerically.
λ = +7 μC/m,
L = 4
m, s = 3 m
P = _____ N/C î + _____ N/C
j
The figure...
A finite line of charge with linear charge density A 3.35 x10 Clm, and length L-0.654 m is located along the x axis (from xa 0 to x = L). A point charge of q =-6.22 x 10' C is located at the point xo 1.56 m, yo 4.50 m. Find the electric field (magnitude and direction as measured from the +x axis) at the point P which is located along the x axis at XP-11.7 m. The Coulomb force...
8 A semi-infinite thin rod has a uniform linear positive charge density λ and is located along the x-axis between x = x° (>0) and x = +ㆀ. Find the electric field at the origin. Hint: Ja .2 = a-b A.의 dx 1 B. 一巡i E. zero
8 A semi-infinite thin rod has a uniform linear positive charge density λ and is located along the x-axis between x = x° (>0) and x = +ㆀ. Find the electric field at...