Homework Answers
(B) no
Gaussian surface gives an idea to find the electric field surrounding a charged particles. It is not valid in case of dipoles.
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PartA Can you draw a Gaussian surface that offers a simple way to compute the electric...
Question 11: Can you calculate the electric field of a dipole using Gauss' Law? If yes,...
Question 11: Can you calculate the electric field of a dipole using Gauss' Law? If yes, sketch the Gaussian surface you would use. If no, explain why not, including a sketch. 3 Using Gauss' Law to calculate the electric field of a spherical object Question 12: a) What is the volume charge density p= for a uniformly charged solid sphere of radius R and with total charge Q? Sketch a graph of p as a function of radius, r; mark...
1: True or false- There is a cubical Gaussian surface with sides of 10.0 cm in...
1: True or false- There is a cubical Gaussian surface with sides of 10.0 cm in length. This Gaussian cube exists in a uniform electric field produced by a charged plane some distance away. The electric flux, F, through this surface has a value of zero. 2: Choose ALL of the geometries in which Gauss' law can be applied. In other words, choose all the geometries that you can build to use Gauss' law. •Sphere •Cylinder •Parallelogram •Pyramid •Octogon •Cube...
(Gauss' law 3) The Gaussian surface is a sphere with a radius of 10 cm. At...
(Gauss' law 3) The Gaussian surface is a sphere with a radius of 10 cm. At the center of the sphere is a point charge. At the Gaussian surface (10 cm from the point charge) an electric field of 5000 N/C is directed away from the point charge. a) Draw the Gaussian surface around the point charge. Show electric field vectors at the surface. b) Use Gauss' law to find the charge enclosed by the surface. c) The charge you...
A charged point particle is placed at the center of a spherical Gaussian surface. The electric...
A charged point particle is placed at the center of a spherical Gaussian surface. The electric flux te is changed if: Select one: O the point charge is moved off center (but still inside the original sphere) O a second point charge is placed just outside the sphere o the point charge is moved to just outside the sphere O the sphere is replaced by a cube of one-tenth the volume O the sphere is replaced by a cube of...
Please answer WARM-UP and PREDICTION. PROBLEM #1: ELECTRIC FIELD VECTORS As part of your internship with...
Please answer WARM-UP and PREDICTION.
PROBLEM #1: ELECTRIC FIELD VECTORS As part of your internship with a local power company, you have been assigned to a team reviewing published research about the effects of electric fields on human health. To evaluate the merits of apparently conflicting research, you need a computer program to simulate the electric field due to complicated charge configurations. Your team leader has assigned you the task of evaluating such a program. To test the program, you...
"question 2 from pset 2" 4. Place an electric dipole in the electric field you found...
"question 2 from pset 2"
4. Place an electric dipole in the electric field you found in problem 9 on PSET 2, such that the dipole moment points along the positive x-axis. In a figure, show the direction of the electric field, the dipole moment and the torque exerted by this field on the dipole. Determine the torque on the dipole due to the external electric field, and the work that the electric field does to rotate the dipole into...
3.1 Pre-lab In the lab on electric potential and electric field lines, you noted that charged...
3.1 Pre-lab In the lab on electric potential and electric field lines, you noted that charged par- ticles produce electric fields and these electric fields, in turn, act on charged par- ticles. However, you then proceeded to produce an electric field geometry using conductors held at a particular electric potential. What happened to the electric charges? Electric charge and electric potential are closely related to each other. Putting charge on a conductor raises its electric potential. It is usually much...
Suppose you choose a cylinder as your Gaussian surface in a constant electric that points in...
Suppose you choose a cylinder as your Gaussian surface in a constant electric that points in the ty direction (as shown).: a) What would be the electric flux through the top surface of the cylinder? Write your answer in terms of the the given variables (E, r, top (b) What would be the electric flux through the bottom surface of the cylinder? Write your answer in terms of the the given variables (E, bottom- (c) What would be the electric...
I. An equipotential surface is a surface of constant potential. II. The electrostatic force does no...
I. An equipotential surface is a surface of constant potential. II. The electrostatic force does no work on a charge that moves along an equipotential surface. III. The equipotential surfaces surrounding a point charge consist of an infinite number of concentric spherical shells IV. Electric field lines are everywhere perpendicular to equipotential surfaces. O I only OI and II only III and IV only O All of the above The electric potential is constant throughout a certain region of space....
Can you draw the electric field lines?
Can you draw the
electric field lines?
Question 11: Can you calculate the electric field of a dipole using Gauss' Law? If yes, sketch the Gaussian surface you would use. If no, explain why not, including a sketch. 3 Using Gauss' Law to calculate the electric field of a spherical object Question 12: a) What is the volume charge density p= for a uniformly charged solid sphere of radius R and with total charge Q? Sketch a graph of p as a function of radius, r; mark...
A charged point particle is placed at the center of a spherical Gaussian surface. The electric flux te is changed if: Select one: O the point charge is moved off center (but still inside the original sphere) O a second point charge is placed just outside the sphere o the point charge is moved to just outside the sphere O the sphere is replaced by a cube of one-tenth the volume O the sphere is replaced by a cube of...
Please answer WARM-UP and PREDICTION.
PROBLEM #1: ELECTRIC FIELD VECTORS As part of your internship with a local power company, you have been assigned to a team reviewing published research about the effects of electric fields on human health. To evaluate the merits of apparently conflicting research, you need a computer program to simulate the electric field due to complicated charge configurations. Your team leader has assigned you the task of evaluating such a program. To test the program, you...
"question 2 from pset 2"
4. Place an electric dipole in the electric field you found in problem 9 on PSET 2, such that the dipole moment points along the positive x-axis. In a figure, show the direction of the electric field, the dipole moment and the torque exerted by this field on the dipole. Determine the torque on the dipole due to the external electric field, and the work that the electric field does to rotate the dipole into...
3.1 Pre-lab In the lab on electric potential and electric field lines, you noted that charged par- ticles produce electric fields and these electric fields, in turn, act on charged par- ticles. However, you then proceeded to produce an electric field geometry using conductors held at a particular electric potential. What happened to the electric charges? Electric charge and electric potential are closely related to each other. Putting charge on a conductor raises its electric potential. It is usually much...
Suppose you choose a cylinder as your Gaussian surface in a constant electric that points in the ty direction (as shown).: a) What would be the electric flux through the top surface of the cylinder? Write your answer in terms of the the given variables (E, r, top (b) What would be the electric flux through the bottom surface of the cylinder? Write your answer in terms of the the given variables (E, bottom- (c) What would be the electric...
I. An equipotential surface is a surface of constant potential. II. The electrostatic force does no work on a charge that moves along an equipotential surface. III. The equipotential surfaces surrounding a point charge consist of an infinite number of concentric spherical shells IV. Electric field lines are everywhere perpendicular to equipotential surfaces. O I only OI and II only III and IV only O All of the above The electric potential is constant throughout a certain region of space....
Can you draw the
electric field lines?
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