An object has a charge of 15.0 mC with a velocity of v⃗ =−2.10×104z^v. At a...

At a given instant a -50 nC object is moving with the velocity v⃗ =−2000x^ in...

At a given instant a -50 nC object is moving with the velocity v⃗ =−2000x^ in a region of space that contains a magnetic field B⃗ =0.6x^−0.2z^ and an electric field E⃗ =1500y^+800z^. What is the unit vector that represents the direction of the net acceleration of the object? Enter your answer in the following form: ax,ay,az

An electron with a velocity given by v⃗ =(1.6×105 m/s )x^+(6700 m/s )y^ moves through a...

An electron with a velocity given by v⃗ =(1.6×105 m/s )x^+(6700 m/s )y^ moves through a region of space with a magnetic field B⃗ ==(0.26 T )x^−(0.10 T )z^ and an electric field E⃗ =(220 N/C )x^. Using cross products, find the magnitude of the net force acting on the electron. (Cross products are discussed in Appendix A.) Express your answer using two significant figures.

A particle with a charge of −−1.24××10−8C−8C is moving with instantaneous velocity v⃗ v→ = (4.19××104m/s4m/s)i^i^...

A particle with a charge of −−1.24××10−8C−8C is moving with instantaneous velocity v⃗ v→ = (4.19××104m/s4m/s)i^i^ ++ (−−3.85××104m/s4m/s)j^j^ . 1)What is the force exerted on this particle by a magnetic field B⃗ B→ = (2.70 TT ) i^i^? Enter the xx, yy, and zz 2)What is the force exerted on this particle by a magnetic field B⃗ B→ = (2.70 TT ) k^k^? Enter the xx, yy, and zz

A particle with a charge of −1.24×10−8C is moving with instantaneous velocity v⃗ = (4.19×104m/s)i^ +...

A particle with a charge of −1.24×10−8C is moving with instantaneous velocity v⃗ = (4.19×104m/s)i^ + (−3.85×104m/s)j^ . Part A What is the force exerted on this particle by a magnetic field B⃗  = (1.40 T ) i^? Enter the x, y, and z components of the force separated by commas. Part B What is the force exerted on this particle by a magnetic field B⃗  = (1.40 T ) k^? Please solve and show how you get the z component from...

Negative charge Q=-2.0 mC and mass m=10.0 g moving to the east with velocity v=70.0 m/s...

Negative charge Q=-2.0 mC and mass m=10.0 g moving to the east with velocity v=70.0 m/s enters the region with uniform electric field E=200.0 N/C directed due east. How far into the region with electric field will it move before coming to momentarily stop? Give answer in meters.

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

A positive charge q = 3.20 10-19 C moves with a velocity vector v = (2.00 x̂ + 3.00 y hat - 1.20 ẑ) 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 charge (in unit-vector notation) taking vector B = (2.00 x̂ + 4.00 y hat + 0.900 ẑ) T and vector E = (4.20 x̂ - y hat - 2.00 ẑ) V/m. Fx...

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 =...