A positive charge q = 3.20 10-19 C moves with a velocity vector v = (2.00...

A particle with positive charge q = 2.56 10-18 C moves with a velocity v with...

A particle with positive charge q = 2.56 10-18 C moves with a velocity v with arrow = (3î + 5? ? k) m/s through a region where both a uniform magnetic field and a uniform electric field exist. (a) Calculate the total force on the moving particle, taking B with arrow = (3î + 5? + k) T and E with arrow = (2î ? ? ? 5k) V/m. Fx = N Fy = N Fz = N (b)...

A particle with positive charge q = 4.49 10-18 C moves with a velocity v =...

A particle with positive charge q = 4.49 10-18 C moves with a velocity v = (3î + 5ĵ − k) m/s through a region where both a uniform magnetic field and a uniform electric field exist. (a) Calculate the total force on the moving particle, taking B = (5î + 2ĵ + k) T and E = (5î − ĵ − 2k) V/m. (Give your answers in N for each component.) Fx = N Fy = N Fz =...

A positive charge q = 3.2 x 1019 C moves with a velocity v = (2i...

A positive charge q = 3.2 x 1019 C moves with a velocity v = (2i - 1k) m/s through a region where both a uniform magnetic field B and a uniform electric field E exist. What is the total force on the moving charge (in unit – vector notation) if B = (2i + 2j) T and E = (-2j - 4k ) V/m? Lütfen birini seçin: a. F = 6.4 x 1019 (i - 2j)  N b. F =...

A point charge q1 = 4.80×10−6 C located at the point (0,   0.45  m, 0), has a velocity...

A point charge q1 = 4.80×10−6 C located at the point (0,   0.45  m, 0), has a velocity v⃗ 1= − 6×105 m/sι^+ 3×105 m/s k^ . Point charge q2 = −2.00×10−6 Clocated at the point (0.5  m, 0, 0) has a velocity  v⃗ 2=  5.6×105 m/s j^ − 5.25×105 m/s k^ . 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 = ___, ___,...

A negative charge q = −3.20×10−6 C is located at the origin and has velocity υ⃗...

A negative charge q = −3.20×10−6 C is located at the origin and has velocity υ⃗ =(7.50×104m/s)ι^+((−4.90)×104m/s)j^υ→=(7.50×104m/s)ι^+((−4.90)×104m/s)j^. At this instant what is the magnetic field produced by this charge at the point x = 0.170 m , y = -0.300 m , z = 0? Enter the x, y, and z components of the magnetic field separated by commas.

A small particle with positive charge q=+4.25×10^−4 C and mass m=5.00×10^−5 kg is moving in a...

A small particle with positive charge q=+4.25×10^−4 C and mass m=5.00×10^−5 kg is moving in a region of uniform electric and magnetic fields. The magnetic field is B=4.00 T in the +z-direction. The electric field is also in the +z-direction and has magnitude E=60.0 N/C. At time t = 0 the particle is on the y-axis at y=+1.00 m and has velocity v = 30.0 m/s in the +x-direction. Neglect gravity. What are the x-, y-, and z-coordinates of the...

A proton, with mass 1.67 × 10-27 kg and charge +1.6 × 10-19 C, is sent...

A proton, with mass 1.67 × 10-27 kg and charge +1.6 × 10-19 C, is sent with velocity 7.1 × 104 m/s in the +x direction into a region where there is a uniform electric field of magnitude 730 V/m in the +y direction. What are the magnitude and direction of the uniform magnetic field in the region, if the proton is to pass through undeflected? Assume that the magnetic field has no x-component and neglect gravitational effects. Draw a...

1. A particle of positive charge q and mass m enters parallel uniform electric and magnetic...

1. A particle of positive charge q and mass m enters parallel uniform electric and magnetic fields (of magnitudes E and B, respectively) both directed in the +z direction with a velocity v = v0i perpendicular to both fields. (a) What is the the particle’s initial acceleration? You can give your answer as a vector in component form. (b) What is the radius of the particle’s path (looking down the z-axis) if the magnetic field is B = Bk? Does...