1.Four loads are fixed at the vertices of a perfect
square, as shown in figure 1. Calculate the magnitude and direction
of the force in each of the loads. Calculate the force (magnitude
and direction) felt by a positive test load of 4.15mC just in the
center of the square. Note that mC means micro Coulombs
(1x10-3C).
2.Two charges, q1 = 25C and q2 = -5C, are separated by a distance of 2cm. Find the position (or positions) along that line where the electric field is zero. Calculate the position in which the electrical potential is zero along the same line.
3. An electron is moving with an initial velocity of 30x106m / s parallel and in favor of a uniform electric field of 10,000 N / C, so that the electric field slowly stops the electron. How much distance will the electron travel before stopping? Consider the following kinematics equation to analyze the system: vf2 = vi2 + 2a (xf-xi)
4. A very thin and long cable has a uniform load distribution of 8x10-6C per meter. Calculate the magnitude and direction of the electric field at a distance of 1cm and 1.5m perpendicular to the cable.
1.Four loads are fixed at the vertices of a perfect square, as shown in figure 1....
We have a square where each side is 2cm. At the top-left corner, there is a charge of -3uc. What does the charge need to be at the bottom left corner and the top right corner so that the electric field at the bottom right corner is zero? An electron is released from rest in a uniform electric field. The electron accelerates vertically upward, traveling 4.50m in the first 3.00 mu s after it is released. What is the magnitude...
1. An electron (q = -1.6x10-19 C, m=9.11x10-31 kg) is placed in an electric field of magnitude 3.52x104N/C which points in the positive z direction. Calculate the magnitude and direction of the acceleration of the electron. 2. An electron is initially moving in the +z direction, with a speed v=2.54x105 m/s at z=0. In the region between z=+1.50 cm and z=+2.50 cm, there is a uniform electric field of magnitude 4.10x104 N/C in the +x direction. Outside that region (z...
Three point charges are arranged at the corners of a square as shown. In this problem, we want to determine the electric field at the location of the dot. a) Calculate the strength (magnitude) of the electric field at the dot due to the -10 nC point charge. b) Calculate the strength (magnitude) of the electric field at the dot due to the +10 nC point charge. c) Calculate the strength (magnitude) of the electric field at the dot due to the -5.0...
Within the green dashed circle shown in the figure below, the magnetic field changes with time according to the expression B 8.00 -1.00t2 + 0.800, where B is in teslas, t is in seconds, and R 2.25 cm. xxKxX xxxxXL Bin (a) when t = 2.00 s, calculate the magnitude of the force exerted on an electron located at point P, which is at a distance n 4.50 cm from the center of the circular field region. 136e-19X What is...
1-5 please
Questions 1.2 T The figure above shows two particles, each with a charge of +Q, that are located at the opposite corners of a square of side d. 1. What is the direction of the net electric field at point P? (D) 1 (E) 2. What is the potential energy of a particle of charge +2q that is held at point P? (A) Zero (B) 2 kgQcc) kq (D) 2kqQ (6) 2,2 kgQ d d d d q=3.0...
d/2 d/2 Figure 1: (a) Question 2, (b) Question 3 1. The charges and coordinates of two charged particles held fixed in an ry plane are q+3.0uC, 3.5 cm, y0.50 cm, and 24.0uC, 2 (a) Find the -2.0cm, y2 1.5 cm i. magnitude and ii. direction of the electrostatic force on particle 2 due to particle 1 (b) At what i. z and ії. y coordinates should a third particle of charge g.-+4.0 μC be placed such that the net...
Problem 1 A -2.80 jIC point charge is fixed at the origin of the x axis A-7.80 pC point charge of mass 1.50 grams is moving along the x axis from the "x direction toward the charge at the origin. It has a speed of 22.0 m/s when it is at x -0.800 mIgnore gravity. Calculate (a) the total energy of the-7.80 pC when it is at r-0.800 m. 0.609 (b) the position along the x axis where the speed...
A small object with mass m, charge q, and initial speed v0 5.00x103 m/s is projected into a uniform electric field between two parallel metal plates of length 26.0 cm (Figure 1). The electric field between the plates is directed downward and has magnitude E 800 N/C. Assume that the field is zero outside the region between the plates. The separation between the plates is large enough for the object to pass between the plates without hitting the lower plate....
QUESTION 5 A angular coil of wire H 24 c n by L-34 c and car yng a cu ent of 1.6 A İs one ted with the plane of its loop pe pendicular to a uniform 1.6 T magnetic field as shown in the figure. The coil is then rotated through a 28° angle into the plane. Calculate the torque that the magnetic field exerts on the coil. Hint: In order to help visualize this three-dimensional problem, make a...
Question 2 In the Figure 17 below the value of the chose me te Loop #1: $8.as - 30 Loop #2: B.as - 24 Loop #3: 8.as - 4H Calculate the magnitude of the current Il 120 130 O 3.0 A O 2.5 A 2.0 A 1.5 A Question Figure 11 below shows the electric field lines in three different regions of space (A, B, and C). A proton is moving from R to S in each region. Rank the...