Question

(1) The goal of this problem is to find the electric field inside of a cavity which is cut into a uniformly charged solid cylinder with infinite length. Inside of the cavity, there is no net charge, but this cavity is off-center. To do this, we will consider it as a solid, uniformly positively charged cylinder (with no cavity) added to a solid, uniformly negatively charged cylinder such that + ho _(0)- ho _(0)=0 in the space where the two cylinders coexist ^(1). But in order to add the two fields in this case, the fields have to be calculated from the same origin (see part (c) for more on that). This may sound strange, but imagine a solid object where we've just ionized a bunch of atoms such that most of the material is positively charged. But we leave the electrons in a small cylindrical region off-center. This is equivalent to having a solid cylinder of ALL ions where we then insert a cylinder of electrons to make that section neutral atoms. (a) Find the electric field inside of a solid cylinder with uniform charge density, ho _(0), which is located at the origin. (b) Find the electric field inside of a solid cylinder with uniform charge density, - ho _(0), which is located at the origin. (c) If we shift the negatively charged cylinder from part (b) to be centered at a position vec(p) rather than the origin, what is the location of a random point inside of your negatively charged cylinder as measured from the origin (vec(r)) ? Express this answer in terms of the location of the center of the negatively charged cylinder (vec(p)) and the location of the random point measured from the center of the negative sphere (vec(r)^('))*.^(2) (d) Use parts (a), (b), and (c) to find the electric field inside of a neutral cavity in an otherwise uniformly charged, cylinder. (e) Find the electric field of this cylinder with the cavity outside the cylinder, at a point P which located a distance a from the axis of the cylinder. The vector from the center of the cylinder to point P(vec(a)) is parallel to vec(p). Please complete all parts thank you!!. (1) The goal of this problem is to find the electric field inside of a cavity which is cut into a uniformly charged solid cylinder with infinite length. Inside of the cavity, there is no net charge, but this cavity is off-center.To do this,we will consider it as a solid,uniformly positively charged cylinder (with no cavity added to a solid, uniformly negatively charged cylinder such that +o - Po - 0 in the space where the two cylinders coexist But in order to add the two fields in this case,the fields have to be calculated from the same origin (see part c for more on that.This may sound strange,but imagine a solid object where we've just ionized a bunch of atoms such that most of the material is positively charged. But we leave the electrons in a small cylindrical region off-center. This is equivalent to having a solid cylinder of ALL ions where we then insert a cylinder of electrons to make that section neutral atoms. a Find the electric field inside of a solid cylinder with uniform charge density,Po,which is located at the origin (b) Find the electric field inside of a solid cylinder with uniform charge density,-Po, which is located at the origin. c If we shift the negatively charged cylinder from part(b) to be centered at a position p rather than the origin, what is the location of a random point inside of your negatively charged cylinder as measured from the origin r? Express this answer in terms of the location of the center of the negatively charged cylinder (p and the location of the random point measured from the center of the negative sphere (r d Use parts (a),(b), and (c to find the electric field inside of a neutral cavity in an otherwise uniformly charged, cylinder (e) Find the electric field of this cylinder with the cavity outside the cylinder, at a point P which located a distance a from the axis of the cylinder.The vector from the center of the cylinder to point Pis parallel to p.

          (1) The goal of this problem is to find the electric field inside of a cavity which is cut into a uniformly charged solid cylinder with infinite length. Inside of the cavity, there is no net charge, but this cavity is off-center. To do this, we will consider it as a solid, uniformly positively charged cylinder (with no cavity) added to a solid, uniformly negatively charged cylinder such that +
ho _(0)-
ho _(0)=0 in the space where the two cylinders coexist ^(1). But in order to add the two fields in this case, the fields have to be calculated from the same origin (see part (c) for more on that). This may sound strange, but imagine a solid object where we've just ionized a bunch of atoms such that most of the material is positively charged. But we leave the electrons in a small cylindrical region off-center. This is equivalent to having a solid cylinder of ALL ions where we then insert a cylinder of electrons to make that section neutral atoms.
(a) Find the electric field inside of a solid cylinder with uniform charge density, 
ho _(0), which is located at the origin.
(b) Find the electric field inside of a solid cylinder with uniform charge density, -
ho _(0), which is located at the origin.
(c) If we shift the negatively charged cylinder from part (b) to be centered at a position vec(p) rather than the origin, what is the location of a random point inside of your negatively charged cylinder as measured from the origin (vec(r)) ? Express this answer in terms of the location of the center of the negatively charged cylinder (vec(p)) and the location of the random point measured from the center of the negative sphere (vec(r)^('))*.^(2)
(d) Use parts (a), (b), and (c) to find the electric field inside of a neutral cavity in an otherwise uniformly charged, cylinder.
(e) Find the electric field of this cylinder with the cavity outside the cylinder, at a point P which located a distance a from the axis of the cylinder. The vector from the center of the cylinder to point P(vec(a)) is parallel to vec(p). 
Please complete all parts  thank you!!.
(1) The goal of this problem is to find the electric field inside of a cavity which is cut into a uniformly charged solid cylinder with infinite length. Inside of the cavity, there is no net charge, but this cavity is off-center.To do this,we will consider it as a solid,uniformly positively charged cylinder (with no cavity added to a solid, uniformly negatively charged cylinder such that +o - Po - 0 in the space where the two cylinders coexist But in order to add the two fields in this case,the fields have to be calculated from the same origin (see part c for more on that.This may sound strange,but imagine a solid object where we've just ionized a bunch of atoms such that most of the material is positively charged. But we leave the electrons in a small cylindrical region off-center. This is equivalent to having a solid cylinder of ALL ions where we then insert a cylinder of electrons to make that section neutral atoms. a Find the electric field inside of a solid cylinder with uniform charge density,Po,which is located at the origin (b) Find the electric field inside of a solid cylinder with uniform charge density,-Po, which is located at the origin. c If we shift the negatively charged cylinder from part(b) to be centered at a position p rather than the origin, what is the location of a random point inside of your negatively charged cylinder as measured from the origin r? Express this answer in terms of the location of the center of the negatively charged cylinder (p and the location of the random point measured from the center of the negative sphere (r d Use parts (a),(b), and (c to find the electric field inside of a neutral cavity in an otherwise uniformly charged, cylinder (e) Find the electric field of this cylinder with the cavity outside the cylinder, at a point P which located a distance a from the axis of the cylinder.The vector from the center of the cylinder to point Pis parallel to p.
        
Show more…
1 the goal of this problem is to find the electric field inside of a cavity which is cut into a uniformly charged solid cylinder with infinite length inside of the cavity there is no net cha 95194

Added by Jessica M.

Close

University Physics with Modern Physics
University Physics with Modern Physics
Hugh D. Young 14th Edition
AceChat toggle button
Close icon
Ace pointing down

Please give Ace some feedback

Your feedback will help us improve your experience

Thumb up icon Thumb down icon
Thanks for your feedback!
Profile picture
(1) The goal of this problem is to find the electric field inside of a cavity which is cut into a uniformly charged solid cylinder with infinite length. Inside of the cavity, there is no net charge, but this cavity is off-center. To do this, we will consider it as a solid, uniformly positively charged cylinder (with no cavity) added to a solid, uniformly negatively charged cylinder such that + ho _(0)- ho _(0)=0 in the space where the two cylinders coexist ^(1). But in order to add the two fields in this case, the fields have to be calculated from the same origin (see part (c) for more on that). This may sound strange, but imagine a solid object where we've just ionized a bunch of atoms such that most of the material is positively charged. But we leave the electrons in a small cylindrical region off-center. This is equivalent to having a solid cylinder of ALL ions where we then insert a cylinder of electrons to make that section neutral atoms. (a) Find the electric field inside of a solid cylinder with uniform charge density, ho _(0), which is located at the origin. (b) Find the electric field inside of a solid cylinder with uniform charge density, - ho _(0), which is located at the origin. (c) If we shift the negatively charged cylinder from part (b) to be centered at a position vec(p) rather than the origin, what is the location of a random point inside of your negatively charged cylinder as measured from the origin (vec(r)) ? Express this answer in terms of the location of the center of the negatively charged cylinder (vec(p)) and the location of the random point measured from the center of the negative sphere (vec(r)^('))*.^(2) (d) Use parts (a), (b), and (c) to find the electric field inside of a neutral cavity in an otherwise uniformly charged, cylinder. (e) Find the electric field of this cylinder with the cavity outside the cylinder, at a point P which located a distance a from the axis of the cylinder. The vector from the center of the cylinder to point P(vec(a)) is parallel to vec(p). Please complete all parts thank you!!. (1) The goal of this problem is to find the electric field inside of a cavity which is cut into a uniformly charged solid cylinder with infinite length. Inside of the cavity, there is no net charge, but this cavity is off-center.To do this,we will consider it as a solid,uniformly positively charged cylinder (with no cavity added to a solid, uniformly negatively charged cylinder such that +o - Po - 0 in the space where the two cylinders coexist But in order to add the two fields in this case,the fields have to be calculated from the same origin (see part c for more on that.This may sound strange,but imagine a solid object where we've just ionized a bunch of atoms such that most of the material is positively charged. But we leave the electrons in a small cylindrical region off-center. This is equivalent to having a solid cylinder of ALL ions where we then insert a cylinder of electrons to make that section neutral atoms. a Find the electric field inside of a solid cylinder with uniform charge density,Po,which is located at the origin (b) Find the electric field inside of a solid cylinder with uniform charge density,-Po, which is located at the origin. c If we shift the negatively charged cylinder from part(b) to be centered at a position p rather than the origin, what is the location of a random point inside of your negatively charged cylinder as measured from the origin r? Express this answer in terms of the location of the center of the negatively charged cylinder (p and the location of the random point measured from the center of the negative sphere (r d Use parts (a),(b), and (c to find the electric field inside of a neutral cavity in an otherwise uniformly charged, cylinder (e) Find the electric field of this cylinder with the cavity outside the cylinder, at a point P which located a distance a from the axis of the cylinder.The vector from the center of the cylinder to point Pis parallel to p.
Close icon
Play audio
Feedback
Powered by NumerAI
Jennifer Stoner Ivan Kochetkov
Kathleen Carty verified

Adi S and 89 other subject Physics 103 educators are ready to help you.

Ask a new question

*

Labs

-

Want to see this concept in action?

NEW

Explore this concept interactively to see how it behaves as you change inputs.

View Labs

*

Key Concepts

-
Key Concept
Premium Feature
Explore the core concept behind this problem.
Play button
Key Concept
Premium Feature
Explore the core concept behind this problem.
Your browser does not support the video tag.

*

Recommended Videos

-
a-solid-conducting-spherical-shell-encloses-solid-conducting-sphere-a-charge-of-sq-is-placed-on-the-sphere-and-charge-of-2q-is-placed-on-the-shell-the-radius-of-the-sphere-is-the-inner-radiu-80248

4. A solid conducting spherical shell encloses a solid conducting sphere. A charge of -5q is placed on the sphere and a charge of +2q is placed on the shell. The radius of the sphere is a, the inner radius of the shell is b, and the outer radius of the shell is c. These parameters are shown in the figure below. a. Sketch the electric field lines everywhere and show how the charge is distributed over the conductors. b. Calculate the surface charge density on all the surfaces. c. Since the system is spherically symmetric, the electric field will be purely radial E = Er(r)r̂. Find the expression for Er(r) for all values of r. d. Can you make the electric field equal to zero between the sphere and the shell simply by changing the charge on the shell? Justify your answer. e. Can you make the electric field equal to zero outside the shell simply by changing the charge on the shell? Justify your answer. 5. Consider an infinitely long cylinder that is concentric with the z-axis. It has a radius of a, and it holds a non-uniform volume charge density of ρ = kr, where k is a constant and r is the radial distance from the centre of the cylinder. We would like to calculate the electric field everywhere inside and outside the cylinder. a. Using symmetry arguments, which component(s) of the electric field, Er, Eφ or Ez, will be zero? b. Draw a cross-section of the cylinder and the draw the Gaussian surface that you would use to calculate the electric field inside the cylinder. c. To find the charge enclosed within the Gaussian surface of (b), you must integrate the charge density. You can do this by considering the cylinder to be made up of an infinite number of thin cylindrical shells. Calculate the differential charge in each shell, while remembering that ρ changes with radius, and integrate over the radius from 0 to r to find the total charge within the Gaussian surface. d. Derive expressions for the electric field inside and outside the cylinder. You should get an electric field of kr^2 / (3ε0) r̂ inside the cylinder and ka^3 / (3ε0r) r̂ outside the cylinder. Do these results agree at the surface of the cylinder, where r = a?

Adi S.

question-1-the-figure-shown-above-displays-a-cross-section-of-a-three-dimensional-closed-surface-with-a-flat-top-and-bottom-surface-above-and-below-the-plane-of-the-page-if-there-is-no-flux-through-th

Question 1: The figure shown above displays a cross-section of a three-dimensional closed surface with a flat top and bottom surface above and below the plane of the page. If there is no flux through the top or bottom surface, the electric field is everywhere parallel to the page and is uniform over each face of the surface, which of the following is true? Question 2: The figure above shows a hollow cavity within a neutral conductor of cross sectonal area 5.00 cm2 with a point charge of Q = +7.20 nC inside. What is the net charge on the inside surface of the conductor? Question 3: What is the electric flux through surface E of the figure provided? Question 4: The figure provided shows a metal sphere hanging by an insulating thread within a hollow conducting sphere. A conducting wire extends from the metal sphere through a small hole in the hollow sphere, but without making contact with the metal sphere. A charged rod is then used to transfer positive charge to the protruding wire. After the charged rod has touched the wire and been removed, what is the charge of the inner surface of the hollow sphere?

Vishal G.

a-11-pts-a-cathode-ray-tube-crt-as-shown-in-the-image-at-right-and-the-diagram-below-is-an-evacuated-glass-tube-a-current-runs-through-a-filament-at-the-right-end-of-the-tube-when-the-metal-73858

(a) [1/1 pts] A "cathode ray tube" (CRT), as shown in the image at right and the diagram below, is an evacuated glass tube. A current runs through a filament at the right end of the tube. When the metal filament gets very hot, electrons occasionally escape from it. These electrons can be accelerated away from the filament by applying a potential difference ΔVacc across the metal plates labeled A and B in the diagram. The electrons pass through a hole in plate B and enter the glass sphere. There they pass between the two horizontal metal "deflection" plates labeled C and D. A potential difference ΔVdef can be applied across these plates to deflect the beam of electrons. In front of and in back of the glass sphere are two coils, through which current can be run to produce a magnetic field in the region between the deflection plates. The coils are oriented so they both produce magnetic fields into the page in this region. Which of the accelerating plates, A or B, has a positive charge? A B (b) [1/1 pts] If the potential difference across the deflection plates, ΔVdef, is zero, the electrons in the beam travel in a straight line, as indicated on the diagram by the dashed blue path. However, if ΔVdef is not zero, the electron beam is deflected downward, following the path indicated on the diagram by the dashed red path. If the beam follows the dashed red path, which of the arrows (a-m) above best indicates the direction of the electric field between the deflection plates? a b c d e f g h m (c) [1/1 pts] If a current runs through the coils, there will be a magnetic field in the region between the deflection plates. If the magnetic field made by the coils points into the page in the region between the plates, which arrow (a-m) best indicates the direction of the magnetic force on an electron in the beam? (You can neglect the effect of the Earth's magnetic field, which is small.) a b c d e f g h m (d) [2/2 pts] The accelerating potential difference is measured to be 5 kV. What is the speed of an electron after it passes through the hole in plate B? v = m/s (e) [2/2 pts] Each of the two coils has 300 turns. The average radius of the coil is 5.4 cm. The distance from the center of one coil to the electron beam is half of 5.4 cm. If a current of 0.4 A runs through the coils, what is the magnitude of the magnetic field at a location on the axis of the coils, midway between the coils? (The electron beam passes through this location.) (When deciding whether to use an exact or an approximate formula here, consider the relative magnitudes of the distances involved). |B| = T (f) [2/2 pts] In a particular experiment, the accelerating potential difference Vacc is set to 5 kV. The distance between the deflection plates is 7.2 mm. A current of 0.4 A runs through the coils, and the potential difference Vdef is adjusted until the electron beam again follows the straight line indicated by the dashed blue path. In this situation (electron beam traveling in a straight line), which of the following statements are true? The electric and magnetic forces on an electron in the beam are in opposite directions. The magnetic force on an electron in the beam is in the direction of its motion. The net force on an electron in the beam is zero. The angle between the electric field and the magnetic field in the region is 180 degrees. The electric force on an electron in the beam is equal in magnitude to the magnetic force on the electron. The magnitude of the electric field in the region is equal to the magnitude of the magnetic field in the region. (g) [0/2 pts] What is the value of Vdef required to make the electron beam travel in a straight line? Vdef =

Umar Sohail Q.


*

Recommended Textbooks

-
University Physics with Modern Physics

University Physics with Modern Physics

Hugh D. Young 14th Edition
achievement 1,774 solutions
Physics: Principles with Applications

Physics: Principles with Applications

Douglas C. Giancoli 7th Edition
achievement 1,853 solutions
Fundamentals of Physics

Fundamentals of Physics

David Halliday, Robert Resnick , Jearl Walker 10th Edition
achievement 1,096 solutions

*

Transcript

-
00:01 According to the question, we have an inner sphere, the inner sphere having a charge of minus 5q and it is enclosed by a shell of inner radius, the radius of the radius of the sphere is a, the radius of the inner radius of the shell is b and the outer radius of the shell is c, the outer radius of the shell is c and the charge on the conduct, on the shell is given as plus 2q.
00:41 Now we know that due to the induction, due to the induction of charges, there will be a positive charge induced on the, this side of the shell, inner surface of the shell and this charge will be equals to plus 5q...
Need help? Use Ace
Ace is your personal tutor. It breaks down any question with clear steps so you can learn.
Start Using Ace
Ace is your personal tutor for learning
Step-by-step explanations
Instant summaries
Summarize YouTube videos
Understand textbook images or PDFs
Study tools like quizzes and flashcards
Listen to your notes as a podcast
Continue solving this problem
Create a free account to:
  • View full step-by-step solution
  • Ask follow-up questions with Ace AI
  • Save progress and study later
Continue Free
Join the community

18,000,000+

Students on Numerade


Trusted by students at 8,000+ universities

Numerade

Get step-by-step video solution
from top educators

Continue with Clever
or



By creating an account, you agree to the Terms of Service and Privacy Policy
Already have an account? Log In

A free answer
just for you

Watch the video solution with this free unlock.

Numerade

Log in to watch this video
...and 100,000,000 more!


EMAIL

PASSWORD

OR
Continue with Clever