a) Use the Gauss Law to find the electric field at point P at distance r>R...

Use the Gauss Law to find the E- field resulting from the infinite cylinder of radius...

Use the Gauss Law to find the E- field resulting from the infinite cylinder of radius R=1.2m with the charge density 130 nC/m3 at point P 8 cm from the center of the cylinder. Take k to be 8.99x109 (Nm2/C2). In the answer box enter the magnitude of the field to the nearest tenth of the unit. For full mark, present the full derivation on paper, with diagram of the Gaussian Surface and the full derivation for the field at...

5. PROBLEM: GUASS'S LAW I Use Guass's law to obtain the electric field for each of...

5. PROBLEM: GUASS'S LAW I Use Guass's law to obtain the electric field for each of the following: a) A point charge q. b) An insulatin sphere of radius R and charge Q distributed uniformly throughout the volume. Here you want to find the electric field both inside and outside the sphere. Sketch the field strength as a function of distance from the center of the sphere.

a) Use Gauss’s Law to derive radial dependence of the electric field inside a very long...

a) Use Gauss’s Law to derive radial dependence of the electric field inside a very long cylindrical shell of radius R and surface charge density σ? b) Same as a) except outside the shell? explain it clear plz

Using Gaussis law find the electric feild near the middle of a very long plastic cylinder...

Using Gaussis law find the electric feild near the middle of a very long plastic cylinder of raduis b at point where r<b. The plastic cylinder has a uniform charge density of p.

Consider a very long cylindrical charge distribution of radius R with a uniform charge density rho....

Consider a very long cylindrical charge distribution of radius R with a uniform charge density rho. Calculate the magnitude of the electric field at distance r<R from the axis of this distribution. Derive using gauss law Show all work please

The electric field in a point on the central axis of a uniformly charged very thin...

The electric field in a point on the central axis of a uniformly charged very thin ring is given by the expression: E = (k*lambda*2pi*R)/((x^2 +R^2)^(3/2)) i cap where R is the radius of the ring, lambda is the linear charge density, and x is the distance of the point on the central axis to the center of the ring. Use this expression (do not derive it!) to calculate the field in a point inside a thin shell with uniform...

Find the electric field at distance Y at point p above the straight-line segment of Length...

Find the electric field at distance Y at point p above the straight-line segment of Length L with linear charge density λ. Point p is located at 1/3 L from the left of the line. Hint: in this problem you need to find both X and Y components of the electric field.

Find the electric field at distance Y at point p above the straight-line segment of length...

Find the electric field at distance Y at point p above the straight-line segment of length L with linear charge density λ. Point P is located at 1/3 L from the left end of the line. Hint: in this problem you need to find both X and Y components of the electric field.

[Draw the electric field around Earth. Draw a Gaussian surface and use Gauss’ law, explaining your...

[Draw the electric field around Earth. Draw a Gaussian surface and use Gauss’ law, explaining your steps.] If the Earth were a large conducting sphere, what would the (negative) surface charge density have to be to maintain an electric field of 150.0 N/C at the surface? Use ε0 = 8.85 x 10-12 C2/N m2 and give your answer to 2 s.f.

Use Ampere’s Law to determine the magnetic field as a function of r (distance from the...

Use Ampere’s Law to determine the magnetic field as a function of r (distance from the symmetry axis) both inside and outside an infinitely long cylinder of radius R, carrying a current Iothat is(show all relevant steps and any symmetry arguments in part a, then you don’t have to repeat them in part b): a) uniformly distributed over the surface of the cylinder (i.e., at r = R) b) uniformly distributed throughout the cylinder