The following diagram shows a wire of length L carrying a current i. A magnetic field B is applied in the direction shown. Where does the magnetic force vector point? X i
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- An iron bolt of mass 58.5 g hangs from a string 37.5 cm long. The top end of the string is fixed. Without touching it, a magnet attracts the bolt so that it remains stationary, but is displaced horizontally 25.0 cm to the right from the previously vertical line of the string. Draw a free-body diagram of the bolt. Find the tension in the string. Find the magnetic force on the bolt. magnitude directionCan you please help me with this question. I really appricieted!Consider the figure shown with current 1 = 3.0 A and current 2 = 1 A. What is the magnetic field strength at wire segment b due to current 1 if the distance between the wires is L=3.0 cm Draw the magnetic field from wire 1 and show the direction of this field at segment b. b. What is the resulting force magnitude and direction on wire segment b ( b= 6.0 cm) due to the interaction of current 2 and the magnetic field of current 1? Justify your answer.
- In the figure the current in the long, straight wire is I1 = 6.50 A, and the wire lies in the plane of the rectangular loop, which carries 12.6 A. The dimensions shown are c = 0.100 m, a = 0.150 m, and ℓ = 0.450 m. Find the magnitude and direction of the net force exerted by the magnetic field due to the straight wire on the loop.The magnetic force dFg on a infinitesimal segment of current I is dFs = I dEx B Where di is the displacement vector of the infinitesimal current segment. The total magnetic force on a finite current segment is F = 1J (dL x B) 1. If the magnetic field is uniform in space the magnetic force on current simplifies to FB = {(x5). What is vector in this expression? Choose one. is the length of the current segment is the vector from the point where the current enters the uniform field to the point where the current leaves the uniform field. a. What is the magnetic force on the portions of the wire to the left of the dashed line? • is the current. 2. The magnetic field is zero to the left of the dashed line. The magnetic field to the right of the dashed line is uniform outwards. A current carrying wire goes through the region as shown. b. What is the magnetic force on the bottom wire segment? Write answer in component vector form. c. What is the magnetic force on the slanted wire segment?…An infinitely long single wire with current I1 = 1.5 A and a rectangular wire loop with current I2 = 0.15 A are in the same plane as shown. The dimensions of the loop are a = 0.087 m and b = 0.126 m. The infinite wire is parallel to side AD of the loop and at a distance d = 0.19 m from it. A) Express the magnitude of the magnetic force Fad, from I1 on wire AD in terms of I1, I2, d and the loop dimensions. B) Calculate the numerical value of Fad in N. C) Express the magnitude of the magnetic force Fbc, from I1 on wire BC in terms of I1, I2, a, b, and d. D) Calculate the numerical value of Fbc in N. E) Is the force of Fad repulsive or attractive? F) Is the force of Fbc repulsive or attractive? G) The forces of Fad and Fbc both act on the infinite wire I1. Do they sum to produce a net attractive or repulsive force? H) Calculate the numerical value of the sum of the forces F = Fad - Fbc on the infinite wire in N.
- Force on a Particle As shown in the picture below, you have a particle with a velocity that is traveling into an area of magnetic field. It is traveling at an angle relative to the magnetic field as shown in the image. B (Magnetic Field) Velocity q = 7.00 x 10-6 c v = 40.00 x 10³ m/s e = 30.00 degrees %3D B = 40.00 T Find the magnitude of the Force on the particle. Your Answer: Answer unitsTwo long, parallel wires are separated by 2.61 cm and carry currents of 2.61 A and 4.55 A, respectively. Find the magnitude of the magnetic force F that acts on a 3.45 m length of either wire. N F =A particle with unit charge (q = 1) enters a constant magnetic field B = i + j with velocity v = 21k. Find the magnitude and direction of the force on the particle. Make a sketch of the magnetic field, the velocity, and the force. What is the magnitude of the force on the particle? 21√√2 (Type an exact answer, using radicals as needed.) What is the direction of the force on the particle? Select the correct choice below and fill in the answer box to complete your choice. A. The force is applied at a(n) B. The force is applied at a(n) O c. The force is applied at a(n) angle with the positive x-axis in the xz-plane. angle with the positive x-axis in the xy-plane. angle with the positive y-axis in the yz-plane.
- In the figure, point P2 is at perpendicular distance R = 29.5 cm from one end of straight wire of length L = 13.4 cm carrying current i= 0.783 A. (Note that the wire is not long.) What is the magnitude of the magnetic field at P2? Po R I. Number i UnitsChapter 29, Problem 037 GO In the figure, four long straight wires are perpendicular to the page, and their cross sections form a square of edge length a = 13.0 cm. Each wire carries 5.50 A, and the currents are out of the page in wires 1 and 4 and into the page in wires 2 and 3. In unit-vector notation, what is the net magnetic force per meter of wire length on wire 4? H a —a——xIn the figure below, the current in the long, straight wire is 1 = 4.90 A, and the wire lies in the plane of the rectangular loop, which carries 13.0 A. The dimensions shown are c. = 0.100 m, a = 0.150 m, and l = 0.450 m. Find the magnitude and direction of the net force exerted by the magnetic field due to the straight wire on the loop.