3) Problem 4.36 from chapter 4 (page 229) of the book. For each of the distributions...
The figure below shows two charges on an xy-plane.
a. Calculate the electric potential at points A, B, C, and
D.
b. Calculate the magnitude and direction of the electric field
at the origin (0,0).
c. On the figure, draw a few equipotential lines as well as
some electric field lines that indicate the direction of the
electric field.
d. Sketch the electric potential as a function of x, with x on
the horizontal axis and V(x) on the vertical...
1) Problem 4 from chapter 4 (page 227) of the book. A square with sides of 2 m has a charge of 40 μ Cat each of its four corners. Determine the electric field at a point 5 m above the center of the square
Chapter 28, Problem 020 An electron is accelerated from rest through potential difference V and then enters a region of uniform magnetic field, where it undergoes uniform circular motion. The figure gives the radius r of that motion versus Vi/2. The vertical axis scale is set by rs= 2.7 mm, and the horizontal axis scale is set by Vs1/2= 40.7 Vi/2, What is the magnitude of the magnetic field? V/2 (v/2) (unuu)
Chapter 28, Problem 020 Your answer is partially correct. Try again. An electron is accelerated from rest through potential difference V and then enters a region of uniform magnetic field, where it undergoes uniform circular motion. The figure gives the radius r of that motion versus v1/2. The vertical axis scale is set by r= 2.9 mm, and the horizontal axis scale is set by V, 1/2= 25.7 v1/2. What is the magnitude of the magnetic field? r (mm) v1/2...
Chapter 24, Problem 037 what is the magnitude of the electric field at the point (9.20 İ-4.40」+ 7.70 k ) m if the electric potential is given by V-3.50xyz2, where V is in volts and x, y, and z are in meters?
diagram above each unit on the horizontal axis is 3.00 cm and
each unit on the vertical axis is 3.00 cm. The equipotential lines
in a region A) Determine the magnitude of the electric field in
this region. V/m B)Determine the shortest distance for which the
change in potential is 3 V.
BACK Chapter 22, Problem 031 Your answer is partially correct. Try again In the figure a nonconducting rod of length L-8.46 cm has charge -q-4.36 fC uniformly distributed along its length. (a) What is the linear charge density of the rod? What are the (b) magnitude and (c) direction (positive angle relative to the positive direction of the x axis) of the electric field produced at point P, at distance a 15.2 cm from the rod? What is the electric...
Chapter 30, Problem 014 In Figure (a), a uniform magnetic field B increases in magnitude with time t as given by Figure (b), where the vertical axis scale is set by B, 12 mT and the horizontal scale is set by ts 4.9 s. A circular conducting loop of area 8.0 × 10-4 m2 lies in the field, in the plane of the page. The amount of charge q passing point A on the loop is given in Figure (c)...
In the diagram below each unit on the horizontal axis is 6.00 cm
and each unit on the vertical axis is 6.00 cm. The equipotential
lines in a region of uniform electric field are indicated by the
blue lines. (Note that the diagram is not drawn to scale.)
(a) What is the direction of the electric field?
THE IMAGE IS NOT MISSING IT IS THE IMGUR LINK BELOW:
https://i.imgur.com/xHQinGw.png
Figure will not post any other way, its says link is...
Chapter 28, Problem 019 A certain particle is sent into a uniform magnetic field, with the particle's velocity vector perpendicular to the direction of the field. The figure gives the period T of the particle's motion versus the inverse of the field magnitude B. The vertical axis scale is set by Ts-52.3 ns, and the horizontal axis scale is set by B, 3.3T1. What is the ratio m/q of the particle's mass to the magnitude of its charge? -1 B-1...