See figure below: The left blue wire of length I is dragged to the right with velocity v over two conductive black rails. Which force does the right blue wire experience?
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Q: A 0.40 µC particle moves with a speed of 19 m/s through a region where the magnetic field has a…
A: It is given that, q=0.40 μC=0.40×10-6 Cv=19 m/sB=0.95 TF=1×10-7 N
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Q: Please help me solve this, I am a bit confused. Thanks!
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Q: QUESTION 4 Find the acceleration in Pm/s2 (1P = 1015) for the electron in problem 22.48.a. using a…
A: The surface charge density of the uniform charge disk is given as, σ=6.94 μC/m2=6.94×10-6 C/m2. The…
Q: Q4: Answer the following Q.4: Two small metallic spheres, each of mass m = 0.200 g, are suspended as…
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A: constant velocity (v) = 126 msmagnitude of electric field = E magnitude of magnetic field (B) = 2.5…
Q: Two small metallic spheres, each of mass m = 0.194 g, are suspended as pendulums by light strings of…
A: mass (m) = 0.194 g charge (q) = 6.6 nC θ = 4.60oLength of string = L
Q: A particle of charge q and mass m moves in the uniform fields E⃗ =E0k^ and B⃗ =B0k^. At t = 0, the…
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- Find the acceleration in Pm/s2 (1P = 1015, for theelectron in problem #48.a. using a chargedensity of o = 3.54 uC/m2.Suppose you were hovering stationary as in question 6 above, except now with sheet charge density 1.11 x 10^-6 C and your mass including the suit 76.1 kg. Suppose that while you were hovering, someone threw you a rock of mass 8.5 kg, and that you caught it. What would now be your rate of acceleration toward the ground? 0.99 m/s^2 9.81 m/s^2 8.82 m/s^2 1.39 m/s^2Three identical charged particles, with an inertia of 0.75 mg carrying +1.5\muC, are held in place formingan equilateral triangle separated by 250 nm. The particles are simultaneously released from rest andbegin to move. How fast is each particle moving when the particles are separated by 750 nm?
- An ideal capacitor has two conducting plate that separated by a distance L, where two plates can have opposite charges (+q and -q). However, in a capacitor, current can flow through this device. Maxwell inserted one term la = €0 to solve the problem. Prove this term is indeed current (has the unit dt of Coulomb/sec).1 |9192 7.2 |F| This problem checks that you can correctly apply Coulomb's law for point charges, Two point-like particles separated by 7 cm have charges 91=2 nC and 92=4 nC. Note that the force felt by each charge due to the other is a vector and has both a magnitude and a direction. What is the magnitude of the force exerted on the charges due to the electromagnetic interaction, in N (10-6 Newtons)? 4π€0(unrealistic) E/M Forces 6. A particle of charge q = 0. 25C and mass m = 1.0kg is moving with a velocity of v = (2,0,0)m/s. The charged particle finds itself in an electric field of E = (8,8,8)N/C and a magnetic field of B = (0,0, -2)T. What will be the initial vector acceleration of the particle?
- A 6.70 -μC particle moves through a region of space where an electric field of magnitude 1250 N/C points in the positive a direction, and a magnetic field of magnitude 1.25 T points in the positive z direction. Part A If the net force acting on the particle is 6.23x10-³ N in the positive direction, find the components of the particle's velocity. Assume the particle's velocity is in the x-y plane. Enter your answers numerically separated by commas. IVE ΑΣΦ Vz, Vy, Uz = ? m/sIn the figure below, q1 = 1.50×10^−7 C and q2 = 3.50×10^−7 C 1)What is the x component of the force F⃗ acting on an proton at that position? (Express your answer to three significant figures.) 2)What is the y component of the force F⃗ acting on an proton at that position? (Express your answer to three significant figures.)A small block of mass m and charge Q is placed on an insulated, frictionless, inclined plane of angle as in the figure below. An electric field is applied parallel to the incline. Q m E = (a) Find an expression for the magnitude of the electric field that enables the block to remain at rest. (Use any variable or symbol stated above along with the following as necessary: g for the acceleration due gravity. Note that the charge of Q is unknown.) i (b) If m = 5.41 g, Q = -7.49 μC, and 0 = 26.3°, determine the magnitude and the direction of the electric field that enables the block to remain at rest on the incline. magnitude N/C direction ---Select---
- Given the arrangement of charged particles in the figure below, find the net electrostatic force on the q₁ = 5.25-μC charged particle. (Assume 92 = 12.33 μC and 93 = -17.12 μC. Express your answer in vector form.) 7 8970000i - 9035000j 9₁ (-2.00 cm, 0) X N 93 (1.00 cm, 1.00 cm) ● 92 (0, -1.00 cm)Part a and C please and thank you When a particle of charge q>0 moves with a velocity of v⃗1 at 45.0∘ from the +x-axis in the xy-plane, a uniform magnetic field exerts a force F⃗1 along the−z-axis (the figure (Figure 1)). When the same particle moves with a velocity v⃗2 with the same magnitude as v⃗1 but along the +z-axis, a force F⃗2 of magnitude F2 is exerted on it along the +x-axis. Part A What is the magnitude (in terms of q, v1, and F2) of the magnetic field? Part C What is the magnitude of F⃗1 in terms of F2?Consider a right-hand Cartesian coordinate system as shown in Figure 14.3 on page 701. We have a wire along the x-axis carrying 12 A in the positive x direction and a constant flux density of 0.3 T directed in the positive z direction. a. Determine the force and its direction on a 0.2 m length of the wire. b. Repeat if the field is directed in the positive x direction.