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

12-A spherical ball of charged particles has a uniform charge density. From Gauss’s Law, derive equations...

12-A spherical ball of charged particles has a uniform charge density. From Gauss’s Law, derive equations for the electric field magnitude as a function of radius, inside, and outside, of the ball. Sketch and label a graph to illustrate this variation. (c) A Geiger counter is used to detect ionizing radiation. For this device, a positively charged central wire is surrounded by a concentric, conducting cylindrical shell with an equal negative charge, creating a strong radial electric field. The shell...

a) By using Gauss’s law, find the electric field inside, outside and inbetween two concentric spherical...

a) By using Gauss’s law, find the electric field inside, outside and inbetween two concentric spherical metal shells, assuming that the inner shell, of radius a, carries a charge of -Q and the outer shell, of radius b, carries a charge of Q. b) By making use of the result in part (a), find the energy stored in the system made of two concentric spherical metal shells. c) By using the result in part (a) find the electric potential difference...

This animation shows a coaxial capacitor with cylindrical geometry: a very long cylinder (extending into and...

This animation shows a coaxial capacitor with cylindrical geometry: a very long cylinder (extending into and out of the page) in the center surrounded by a very long cylindrical shell (position is given in centimeters, electric field strength is given in newtons/coulomb, and electric potential is given in volts). The outside shell is grounded, while the inside shell is at 10 V. You can click-drag to measure the voltage at any position. 1. Use Gauss's law to show that the...

A conducting rod of radius R1= 1 nm and length L=10 nm inside a thin-walled coaxial...

A conducting rod of radius R1= 1 nm and length L=10 nm inside a thin-walled coaxial conducting cylindrical shell of radius R2= 10R1 with the same length L. Use Gauss’s Law (derive the formula) to find the electric field at point “a” located 2R2 mm beyond the surface of the shell. “b” located 5R1 mm within the surface of the shell.

Using Gauss’s Law, answer the following question An insulator of radius, a = 3 cm is...

Using Gauss’s Law, answer the following question An insulator of radius, a = 3 cm is placed inside an SPHERICAL shell conductor of inner radius b = 7 cm and outer radius c = 12 cm. The conductor has a total charge of Q = - 10 nC. The insulator has a charge distributed around its volume with charge density ρ, where the value of ρo = 2 ∗ 10−4  C/m3 . a) Compute the value of the TOTAL charge of...

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...

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

Finding the electric field using Gauss’s law may seem to be a hopeless task. After all,...

Finding the electric field using Gauss’s law may seem to be a hopeless task. After all, while the electric field does appear in the equation, it is only the normal component that emerges from the dot product, and it is only the integral of that normal component over the entire surface that is proportional to the enclosed charge. (ii) Do realistic situations exist in which it is possible to dig the electric field out of its interior position in Gauss’s...

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 solid spherical charge insulator of radius R carries a uniform charge density of p. A)...

A solid spherical charge insulator of radius R carries a uniform charge density of p. A) Derive an equation for the electric field as a function of the radical position inside the sphere using electric flux and a Gaussian surface of variable radius. B) Derive an equation for the electric field as a function of the radial position outside the sphere. C) Multiply your results from parts A and B with some test charge, are these results consistent with coulombs...