Question

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

Homework Answers

Answer #1

The concept used in this is net force acting on an object of mass m when passes through a magnetic field and the electric field , after applying this concept i deduced the magnitude of the acceleration in x , y and z direction.

kindly upvote my anwer , if you like , by clicking on the like button.

Know the answer?
Your Answer:

Post as a guest

Your Name:

What's your source?

Earn Coins

Coins can be redeemed for fabulous gifts.

Not the answer you're looking for?
Ask your own homework help question
Similar Questions
An object has a charge of 15.0 mC with a velocity of v⃗ =−2.10×104z^v. At a...
An object has a charge of 15.0 mC with a velocity of v⃗ =−2.10×104z^v. At a given instant, the particle enters a region of space that has both a magnetic field of B⃗ =−2.00×10−6x^B and an electric field of E⃗ =−12.0x^−4.00y^E. What is the force vector felt by this charge? You must get all three parts of this question entirely correct in order to get your points back for the two questions this corresponds to from the exam.
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 proton moves through a region of space where there is a magnetic field B⃗ =(0.65i+0.37j)T...
A proton moves through a region of space where there is a magnetic field B⃗ =(0.65i+0.37j)T and an electric field E⃗ =(3.1i−4.4j)×103V/m. At a given instant, the proton's velocity is v⃗ =(5.4i+2.9j−5.1k)×103m/s. Find Fx, Fy, Fz in N
A proton moves through a region of space where there is a magnetic field B⃗ =(0.64i+0.40j)T...
A proton moves through a region of space where there is a magnetic field B⃗ =(0.64i+0.40j)T and an electric field E⃗ =(3.3i−4.5j)×103V/m. At a given instant, the proton's velocity is v⃗ =(6.6i+2.8j−4.8k)×103m/s. At a given instant, the proton's velocity is v⃗ =(6.6i+2.8j−4.8k)×103m/s. Determine the components of the total force on the proton. Express your answers using two significant figures. Enter your answers numerically separated by commas. Please circle the answer
A proton moves through a region of space where there is a magnetic field B⃗ =(0.57i+0.37j)T...
A proton moves through a region of space where there is a magnetic field B⃗ =(0.57i+0.37j)T and an electric field E⃗ =(2.7i−4.0j)×103V/m. At a given instant, the proton's velocity is v⃗ =(7.0i+2.8j−4.9k)×103m/s. Determine the components of the total force on the proton. Fx, Fy, Fz =
A proton moves through a region of space where there is a magnetic field B⃗ =(0.64i+0.40j)T...
A proton moves through a region of space where there is a magnetic field B⃗ =(0.64i+0.40j)T and an electric field E⃗ =(3.3i−4.5j)×103V/m. At a given instant, the proton's velocity is v⃗ =(6.6i+2.8j−4.8k)×103m/s. Determine the components of the total force on the proton. Express your answers using two significant figures. Enter your answers numerically separated by commas.
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...
A particle with charge − 5.10 nC is moving in a uniform magnetic field B⃗ =−(...
A particle with charge − 5.10 nC is moving in a uniform magnetic field B⃗ =−( 1.25 T )k^. The magnetic force on the particle is measured to be F⃗ =−( 4.00×10−7 N )i^+( 7.60×10−7 N )j^ . Part A Are there components of the velocity that are not determined by the measurement of the force? yes no Part D Calculate the scalar product v⃗ ⋅F⃗. v⃗ ⋅F⃗ m/s⋅N Request Answer Part E What is the angle between v⃗ and...
At some instant the velocity components of an electron moving between two charged parallel plates are...
At some instant the velocity components of an electron moving between two charged parallel plates are vx=2.0×105 m/s and vy=3.1×103 m/s. Suppose the electric field between the plates is uniform and given by E→=(120N/C)j. In unit-vector notation, what are (a) the electron’s acceleration in that field and (b) the electron’s velocity when its x coordinate has changed by 2.4 cm?