A point charge in placed at the origin in a dielectric material with εr1 =6 and results in flux exiting the closed sphere at r = 1 equal to 30 nC. If the same point charge is placed in another dielectric material with εr2 =2, what will the total flux exiting the sphere r = 1 be equal to?

A point charge in placed at the origin in a dielectric material with εr1 =6 and results in flux exiting the closed sphere at r = 1 equal to 30 nC. If the same point charge is placed in another dielectric material with εr2 =2, what will the total flux exiting the sphere r = 1 be equal to?

College Physics

1st Edition

ISBN:9781938168000

Author:Paul Peter Urone, Roger Hinrichs

Publisher:Paul Peter Urone, Roger Hinrichs

Chapter18: Electric Charge And Electric Field

Section: Chapter Questions

Problem 42PE: (a) Find the total electric field at x = 1.00 cm in Figure 18.52(b) given that q =5.00 nC. (b) Find...

See similar textbooks

Related questions

Q: Suppose that there is a charged conductor that is solid and spherical. Choose which statements is or…

A: Correct option is (II) and (III) (II) The electric field inside the sphere is equal to zero. (III)…

Q: If more electric field lines leave a closed (Gaussian) surface than enter it, what can you conclude…

A: The electric field at a point in space is defined as the ratio of the electric force experienced per…

Q: A solid, conducting sphere of radius a has a total charge Q. Concentric with this sphere is an…

Q: A charged nonconducting rod has a length L of 2.0 m and a cross-sectional area A of 8.0 cm?; it is…

A: Given: Length of rod, l = 2 m Area of rod, A = 8 cm2 = 8 X 10-4 m2 Volume charge density, pu = -10…

Q: Two metal spheres, one of radius R and the other of radius 2R, both have same surface charge density…

A: Total charge on sphere 1: Q1=σ(4πR2)Q1=4πR2σ Similarly, total charge on sphere 2:…

Q: You have a cube with a 6µC charge in the center. Each of the cube's sides is 12cm long. What is the…

Q: Suppose that a conducting sphere is charged positively by some method. The charge is initially…

Q: Charge is placed on the surface of a 2.7-cm radius isolated conducting sphere. The surface charge…

A: Given: The radius of the sphere is 2.7 cm. The surface charge density is 6.9x10-6 C/m2.

Q: Charge is placed on the surface of a 2.7cm radius isolated conducting sphere. The surface charge…

A: Radius, r = 0.027 mSurface charge density, σ = 6.9×10-6 C/m2 The area of sphere is A = 4πr2A =…

Q: A small mass charged sphere ( q=D 3 µC) is attached by an insulating string to the surface of a very…

A: Charge on Sphere=q=3x10-6 C Surface Charge Density=σ=54.2x10-6 C ε∘=8.8542x10-12 Fm-1

Q: A solid copper sphere has a net positive charge. The charge is distributed uniformly over the…

A: Answer:The following is the schematic diagram of the charge having a positive charge. (1)When a…

Q: Red blood cells can be modeled as spheres of 7.03 µm diameter with –2.55 × 10-12 C excess charge…

A: Given: The diameter of the sphere = 7.03 x 10-6 m Charge on the sphere = -2.55 x 10-12 C…

Q: A conductor sphere of radius a carries a free charge Q and is surrounded by a dielectric sphere of…

A: In this question we are given that a conductor carries a free charge Q and is surrounded by a…

Q: A solid sphere of radius a is centered at the origin. It is made of an insulating material and…

A: Given, Q1 = +10 μCQ2 = -5 μCa = 5 cmb = 15 cmc = 20 cmFind electric field at x = 30 cm

Q: A small mass charged sphere (q= 3 µC ) is attached by an insulating string to the surface of a very…

Q: At what point is the charge per unit area greatest on the surface of an irregularly shaped…

Q: In part (a) of the figure an electron is shot directly away from a uniformly charged plastic sheet,…

Q: If a cell has a net charge of -8.65 pC, what are the magnitude anf direction (inward or outward) of…

A: From Gauss’s law, net flux through the cell boundary is given by, ϕ=Qenclosedε0

Q: An electric dipole is oriented in the uniform electric field with magnitude 200 N/C as shown. What…

A: The torque exerted on a dipole due to an external electric field is:

Q: Problem 1: Derive Equation 23.11 of the textbook for the field Edipole in the plane that bisects an…

Q: A square surface of area 2 cm2 is in a space of uniform electric field of magnitude 103 N/C . The…

A: Given data: The square surface area is: A = 2 cm2 The uniform electric field is: E = 103 N/C The…

Q: Consider a long, uniformly charged, cylindri- cal insulator of radius R with charge density 1.7…

Q: A long, straight wire has fixed negative charge with a linear charge density of magnitude 3.6 nC/m.…

A: The expression for net electric is,

Q: The surfaces of a lipid bi-layer forming the membrane around a cell with a radius of 1.2 µm has a…

Q: An insulating sphere is 4.00 cm in radius and carries a 5.80 µC charge uniformly distributed…

A: If an amount of charge Q is distributed throughout the interior volume of an insulator of radius R,…

Q: The electric flux density D inside a dielectric sphere of radius a centered at the origin is given…

A: Given that, Electric flux density D= ρoR C/m² Radius= a

Q: A thin conducting plane with surface charge density o is exposed to an external electric Eext. The…

A: Recall E=σ/2ε0=electric field due to sheet of charge.

Q: In the figure a "semi-infinite" nonconducting rod (that is, infinite in one direction only) has…

Q: A coaxial cable consists of a wire of radius a surrounded by a thin metal cylin-drical shell of…

A: (a) Sketch of field lines for the cable

Q: A solid block of copper, which is a good conductor, has a cavity in its interior. Within the cavity,…

Q: You have a cube with a 6µC charge in the center. Each of the cube's sides is 12cm long. What is the…

A: Given data: A cube have change at center Charge (q) = 6 μC = 6×10-6 C Required: The flux through…

Q: A charge q sits at the back corner of a cube, as shown. The length of the edge of the cube is L and…

Q: A solid insulating sphere has total charge Q and radius R. The sphere's charge is distributed…

A: the electric field inside a solid insulating sphere is given by the following relation E = kQr / R3…

Q: A line of charge starts at x = + xo and extends to positive infinity. The linear charge density is a…

A: Linear charge density of the line charge (λ)=λ0x0x

Q: A thin rod of length L = 1 m lies along the x axis with its left end at the origin. It has a uniform…

Q: A cylindrical distribution of charge ρ = α /√ r where α = 2 µC/m 5/2 extends from 0 cm to 9.3 cm .…

A: Given: The distance at which the electric field is to be determined is r=3.53 cm=3.53×10-2 m α=2…

Q: Enet separated by a distance d = 75 [cm]. The plates are insulating and have charge densities to…

Q: At t = 0 , a particle is traveling parallel to very large insulating plate at a 0.360 m distance…

A: Charge density, σ=2.34×10-9 C/m2 Charge of proton is e=1.6×10-19 C Electric field due to proton is…

Q: Total charge Q is non-uniformly distributed over an insulating sphere of radius R. The charge…

A: Given that, Total Charge Q is non uniformly distributed over an insulating sphere of radius R and…

Q: Consider a solid conductor sphere of radius Ra. The sphere is covered uniformly with positive…

Q: You have a cube with a 6uC charge in the center. Each of the cube's sides is 12cm long. What is the…

A: Given that Q = 6×10-6C which is placed at the center of the cube so the electric flux…

Q: Look at the payload system below! The solid insulator sphere (radius a = 9 cm) is in the center of…

Q: An insulating sphere of radius R = 3 cm has positive charge uniformly distributed throughout its…

A: Given : R = 3cm

Q: A solid sphere of radius a is centered at the origin. It is made of an insulating material and…

Q: A region contains a volume charge density p= ax. Ifelectric flux through a sphere of radius R…

Concept explainers

Electric Charges and Fields

One of the fundamental properties is the electromagnetic property. Charge cannot be destroyed by any process and this contributes formally to the law of charge conservation.

Question

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

SEE SOLUTION Check out a sample Q&A here

Step 1

VIEW

Step 2

VIEW

Step by step

Solved in 2 steps with 2 images

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.

Similar questions

Suppose a capacitor consists of two coaxial thin cylindrical conductors. The inner cylinder of radius ra has a charge of +Q, while the outer cylinder of radius rb has charge -Q. The electric field E at a radial distance r from the central axis is given by the function
Suppose a capacitor consists of two coaxial thin cylindrical conductors. The inner cylinder of radius ra has a charge of +Q, while the outer cylinder of radius rb has charge -Q. The electric field E at a radial distance r from the central axis is given by the function: E = αe-r/a0 + β/r + b0
Red blood cells can be modeled as spheres of 7.03 µm diameter with -2.55 × 10-12 C excess charge uniformly distributed over the surface. Find the electric field at the following locations, with radially outward defined as the positive direction and radially inward defined as the negative direction. The permittivity of free space eo is 8.85 × 10-12 C/(V-m). What is the electric field Éj inside the cell at a distance of 3.25 µm from the center?
A cylindrical distribution of charge ρ = α /√ r where α = 2 µC/m 5/2 extends from 0 cm to 9.3 cm . Concentric with this is a dielectric shell with 5.44 of inner radius 16.6 cm and outer radius 24.9 cm . What is the electric field at 3.53 cm ?
HW1: Region y 0 is a dielectric medium (€,-1 = 2). If there is a surface charge of p, = 2 n on the conductor, determine E and D at (a) A (3,-2,2) (b) B (-4,1,5)
When the electric field in air exceeds a value of EDB = 3*10^6V/m (the dielectric strength), dielectric breakdown occurs and the air becomes ionized. If the electric field at the surface of a conductor exceeds this value, the ionization of the air will remove charge from the conductor until the electric field no longer exceeds 3*10^6V/m. What is the maximum charge that can be held on a conducting sphere in air in terms of the sphere's radius R and the dielectric strength of air EDB? (in terms, no specific numbers)
A system consists of a ball of radius R carrying a spheri- cally charge and a surrounding space filled with a charge of volume density p = where a is a constant and r is the distance from the centre of the ball. Find the charge on the ball for which the magnitude of electric field strength is electric field strength? The dielectric constant of ball and surrounding may be taken equal to unity.
A dielectric lamina with charge density proportional to y covers the area between the parabola y = 16 − x2 and the x axis. Find the total charge.
Ex:Region y 0 is a dielectric medium (€,r1 = 2). If there is a surface charge of p, = 2 n (а) А (3,-2,2) (b) В (-4,1,5) on the conductor, determine E and D at т2
Suppose a capacitor consists of two coaxial thin cylindrical conductors. The inner cylinder of radius ra has a charge of +Q, while the outer cylinder of radius rb has charge -Q. The electric field E at a radial distance r from the central axis is given by the function: (refer to img below)
If the magnitude of an electric field in air is as great as 3.00×106 N/C, the air becomes ionized and begins to conduct electricity. This phenomenon is called dielectric breakdown. A charge of 27.8 μC is to be placed on a conducting sphere. What is the minimum radius of a sphere that can hold this charge without breakdown?
A square surface of area 2 cm2 is in a space of uniform electric field of magnitude 103 N/C . The amount of flux through it depends on how the square is oriented relative to the direction of the electric field. Find theelectric flux through the square, when the normal to it makes the following angles with electric field: (a) 30° , (b) 90° , and (c) 0° . Note that these angles can also be given as 180° + θ .