In the figure, a small particle of charge q = –1.9 x 10–6 C and mass m = 3.1 x 10–12 kg with speed v0 = 8.1x103 m/s as it enters a region of uniform magnetic field. The particle is initially traveling perpendicular to the magnetic field and is observed to travel in the semicircular path shown with radius R = 5.0 cm. Find the magnitude of the magnetic field in Teslas.

In the figure, a small particle of charge q = –1.9 x 10–6 C and mass m = 3.1 x 10–12 kg with speed v0 = 8.1x103 m/s as it enters a region of uniform magnetic field. The particle is initially traveling perpendicular to the magnetic field and is observed to travel in the semicircular path shown with radius R = 5.0 cm. Find the magnitude of the magnetic field in Teslas.

Similar questions

A single ionized atom, that is deficient one electron, is traveling at in a straight line when it enters a uniform magnetic field of strength 0.750 T. The ion is traveling in the plane of the page, while the magnetic field points into the page. (See the diagram below.) If the mass of the ionized atom is 6.68 x 10-27 kg, what is the frequency in Hz of the resultant circular motion? The charge of a single electron is 1.602 x 10-19 C. a. 7.47 MHz b. 6.33 MHz c. 4.13 MHz d. 3.50 MHz e. .2.86 MHz
A particle having mass m = 2.80E-4 kg carries a negative charge q= −1.70E-6 C . The particle is given an initial velocity in the −y direction (downward), as shown in the figure, of v = 3.65E2 m/s. Everywhere in space there is a uniform constant magnetic field B = 0.340 T pointing in the +z direction, which is out of the plane of the page. What is the radius of the cyclotron orbit trajectory that this particle will move along (in m)?
As shown in the figure, a small particle of charge q= 6.3 µ C and mass 3.84 x 1012 kg has velocity 9.0 x 10° m/s as it enters a region of uniform magnetic field. The particle is observed to travel in the semicircular path shown, with radius R= 5.0 cm. Calculate the magnitude and direction of the magnetic field in the region in T. If the field is into the page, give a negative number. If the field is out of the page, give a positive number. Region of magnetic field R Path of the particle
This time I1 = 9.01, I2 = 1.40 A, and the two wires are separated by 8.41 cm. Now consider the charge q = 5.09 x 10^-6 C, located a distance of 7.00 cm to the right of wire I2, moving to the right at speed v = 66.0 m/s. What is the magnitude of the total magnetic force on this charge? 2.21E-09 N 1.11E-09 N 5.27E-09 N 3.69E-09 N
A particle having mass m = 2.80E-4 kg carries a negative charge q= −1.70E-6 C . The particle is given an initial velocity in the −y direction (downward), as shown in the figure, of v = 3.65E2 m/s. Everywhere in space there is a uniform constant magnetic field B = 0.340 T pointing in the +z direction, which is out of the plane of the page. What is the radius of the cyclotron orbit trajectory that this particle will move along (in m)?
The diagram above shows segments of two long straight wires, carrying currents. This time I1 = 6.46, I2 = 2.03 A, and the two wires are separated by 1.10 cm. Now consider the charge q = 6.74 x 10^-6 C, located a distance of 6.31 cm to the right of wire I2, moving to the right at speed v = 43.2 m/s. What is the magnitude of the total magnetic force on this charge? 3.34E-09 N 2.00E-09 N 6.95E-09 N 4.17E-09 N
An proton moves with a speed of 5.0 × 10^5 m/s along the +x-axis. It enters a region where there is a magnetic field of 3.0 T, directed in the y-axis. Calculate the magnitude of the acceleration of the proton. (q = 1.60 × 10~19 c, me1 = 1.67 × 1027 kg) O o m/s? O 1.3 x 1018 m/s² O 1.5x 1014 m/s² O 1.3 x 10-18 m/s² O 3.0 x 10-18 m/s²
A charge g = +1.60E-12 C moves with speed 4.324 m/s through a constant magnetic field of strength 5.65 T. The charge's velocity vector makes an angle of 25.1° with the direction of the magnetic field. What is the magnetic force exerted on the charge (in Newtons (N))?
A uniform magnetic field of magnitude 0.14 T is directed along the positive x-axis. A positron moving at a speed of 4.95x10^6 m/s enters the field along a direction that makes an angle of θ = 85° with the x-axis. The motion of the particle is expected to be a helix. Calculate the pitch p of the trajectory.
004 A long straight wire lies on a horizontal table and carries a current of 0.59 µA. A proton
The figure shows a particle that carries a charge of qo= -2.48 x 106 C. It is moving along the +y axis at a speed of v=4.62 x 10 m/s. A magnetic field B of magnitude 3.38 x 105 T is directed along the +z axis, and an electric field of magnitude 134 N/C points along the-x axis. Determine (a) the magnitude and (b) direction (as an angle within x-y plane with respect to +x-axis in the range (-180°, 180%]) of the net force that acts on the particle. (a) Number i My (b) Number +X Units Units 40
A particle having mass m = 2.80E-4 kg carries a negative charge q= −1.70E-6 C . The particle is given an initial velocity in the −y direction (downward), as shown in the figure, of v = 2.41E2 m/s. Everywhere in space there is a uniform constant magnetic field B = 0.340 T pointing in the +z direction, which is out of the plane of the page. What is the the magnetic force that B exerts on the particle (in N; use positive sign if the force points in the +x direction and negative sign if the force points in the −x direction)?