
The uniform magnetic field of 0.15 T intensity is oriented along
the positive x-axis as in the figure. Let's assume that a positron
(positive electron) moving at a speed of v = 5x10 ^ 6 m / s enters
the field with the x-axis in the direction that turns theta = 85
degrees.
According to this;
a) Find the horizontal and vertical components of the V
velocity.
b) Orbit p step (path taken in the x-axis direction at the end of a
period)
c) Calculate the radius r of the orbit.
d) Write the T period of the movement

The uniform magnetic field of 0.15 T intensity is oriented along the positive x-axis as in...
1. A uniform magnetic field of magnitude B= 10 T is oriented along the positive x-axis and a particle with a charge of +5 uc enters the field with a constant velocity of 20 m/s from left to right at an angle of 30° above the x-axis. A. Illustrate the problem and label the illustration in detail. (5 pts) B. Calculate the magnitude and direction of the magnetic force on the particle. (5 pts) 2. Two long straight wires are...
A uniform magnetic field of magnitude 0.150 T is directed along the positive x-axis. An electron moving at 10.00 x 106 m/s enters the field along a direction that makes an angle of 60.0o with the x-axis. The motion of the particle is expected to be a helix. Calculate (a) the pitch p and (b) the radius r of the trajectory.
A uniform magnetic field of magnitude 0.165 T is directed along the positive x axis. A positron moving at a speed of 4.95 Times 10^6 m/s enters the field along a direction that makes an angle of theta = 85.0 degree with the x axis (see figure below). The motion of the particle is expected to be a helix. Calculate the pitch p of the trajectory as defined in figure. Calculate the radius r of the trajectory as defined in...
If there is a magnetic field with a strength of 0.5 T in the positive x-direction, what is the magnitude and direction of the force on a helium atom that has lost all of its electrons that is moving at 45° above the positive x-axis with a speed of 1.0 x 10 cm/s? Give the direction in terms of positive or negative along an axis (e.g. positive x-axis).
4.) 4.) (a) A 50cm long wire with a current of 0.50A
in the positive x direction through x axis
There. A magnetic field given by Tele ?⃗ = 0.0030?̂ + 0.010?̂ ?
acts. Tele-acting
Find the components of the magnetic force.
(b) A battery of V = 10V a 1.50μF capacitor is charged through a
12Ω resistor. Condenser
what is the current when the maximum load ¼ is full? Is the current
at this moment the maximum current ¼...
A charged particle moves along the x-axis through a region with a uniform magnetic field that is oriented to lie in the x-y plane. Part a) Assume that the particle has a net charge of +669 μC and is moving with a velocity of 464 m/s in the +x direction at a particular instant. In that region of space, there is a uniform magnetic field of 1.91T directed in the x-y plane at an angle of +29.8 ∘ relative to...
. An electron is moving (along x-axis) through a 50 T magnetic field (along y-axis) at a perpendicular velocity of 20000 m/s. Find the magnitude and direction of the magnetic force experienced by the electron. having hard time pleases go step by step
An electron is moving (along x-axis) through a 77 T magnetic
field (along y-axis) at a perpendicular velocity of 20000 m/s. Find
the magnitude and direction of the magnetic force experienced by
the electron. (Here is a picture not sure if you need it. if not
disregard.)
I P В.
An electron is moving (along x-axis) through a 50 T magnetic field (along y-axis) at a perpendicular velocity of 20000 m/s. Find the magnitude and direction of the magnetic force experienced by the electron. which law is this using and can you break it down step by step im still not understanding
a wave is travelling with a speed v along the x axis in the
positive direction. The upper graph shows the displacement y versus
the distance x for a given instant of time. The lower graph shows
the displacement y versus the time t for any given point x. From
the information in the graphs, calculate the wave speed v.