An electron (charge e) with a velocity described by the vector v=(2.0, 3.5, 5.5) m/s at an instant in time is traveling through a uniform magnetic field of 6.0 T in the z-direction. Calculate the components of the magnetic force vector on the electron.
A. Fx= 21e
Fy = -12e
Fz= 0
B. Fx= 21e
Fy = -12e
Fz= 33e
C. Fx= 21e
Fy = 12e
Fz= 0
D. Fx= 12e
Fy = 21e
Fz= 0
An electron (charge e) with a velocity described by the vector v=(2.0, 3.5, 5.5) m/s at...
An electron moves in the magnetic field B? = 0.600
i^Twith a speed of 1.30 ×107m/s in the directions shown in
the figure. For each, what is magnetic force
F? on the electron?
Express vector F?
in the form of
Fx,
Fy,
Fz, where the x, y, and z components are
separated by commas.
Express vector F? in the form of
Fx, Fy, Fz,
where the x, y, and z components are separated by
commas.?
ía) 45
At a particular instant, charge q1 = 4.20×10−6 C is at the point (0, 0.250 m, 0) and has velocity υ⃗ 1=(9.20×105m/s)ι^. Charge q2 = −3.40×10−6 C is at the point (0.150 m, 0, 0) and has velocity υ⃗ 2=(−5.30×105m/s)j^. At this instant, what is the magnetic force that q1 exerts on q2? Enter the x, y, and z components of the force separated by commas. Fx,Fy,Fz
An electron moves with velocity v ⃗ =(6.8i−5.3j)× 10 4 m/s in a magnetic field B ⃗ =(−0.64i+0.57j)T . Part A Determine the x-component of the force on the electron. Express your answer using two significant figures. Fx = N Part B Determine the y-component of the force on the electron. Express your answer using two significant figures. Fy = N Part C Determine the z-component of the force on the electron. Express your answer using two significant figures....
1. A particle with an electrical charge of 3.50 nC is traveling with an instantaneous velocity of 5.00 x 104m/s in the positive x-direction. The particle is in a region of uniform magnetic field of 0.0420 T in the negative z-direction. What is the magnetic force that acts on the particle at this instant?
Problem 28.56 1 of 4 At a particular instant, charge q1 = 4.40×10−6 C is at the point (0, 0.250 m, 0) and has velocity υ⃗ 1=(9.20×105m/s)ι^. Charge q2 = −2.50×10−6 C is at the point (0.150 m, 0, 0) and has velocity υ⃗ 2=(−5.30×105m/s)j^. Part A At this instant, what is the magnetic force that q1 exerts on q2? Enter the x, y, and z components of the force separated by commas. Fx F x , Fy, Fz =...
At a particular instant, charge q1 = 4.90×10−6 C is at the point (0, 0.250 m, 0) and has velocity υ⃗ 1=(9.20×105m/s)ι^. Charge q2 = −3.10×10−6 C is at the point (0.150 m, 0, 0) and has velocity υ⃗ 2=(−5.30×105m/s)j^. At this instant, what is the magnetic force that q1 exerts on q2? Fx, Fy, Fz = uN
A particle with a charge of 3.0 C moves through a uniform magnietic field. At one instant the velocity of the particle is ?⃑ = (3.0?̂+ 4.0?̂− 6.0?̂) m/s and the magnetic force on the particle is ?⃑ ? = (−8.0?̂+ 3.0?̂+ 2.0?̂) N. In unit-vector notation, determine the magnetic field B.
(a) A proton, traveling with a velocity of 3.5 106 m/s due east, experiences a magnetic force that has a maximum magnitude of 7.1 10-14 N and a direction of due south. What are the magnitude and direction of the magnetic field causing the force? magnitude T (b) Repeat part (a) assuming the proton is replaced by an electron. magnitude T
An electron that has velocity v=(3x10^5 m/s) and moves along positive x direction through the uniform magnetic field B=(0.8T) which is along the positive z direction. (a) Find the force on the electron (magnitude and direction). (e=1.6x10^-31 kg) (b) Calculate the radius of the electron's path in the magnetic field.
A proton moves in the magnetic field B⃗ =0.56i^T with a speed of
9.0×106 m/s in the directions shown in the figure. (Figure 1)
Part B
In Figure (b), what is the magnetic force
F⃗ on the proton? Give your answers in
component form.
Express vector F⃗
in the form of
Fx,
Fy,
Fz , where the
x,
y, and
z components are separated by
commas.