Multiple ChoiceAt what distance from a wire carrying a 10A current is the magnetic field strength equal to 50μT? This is the approximate value of the Earth's magnetic field.261views
Multiple ChoiceTypical household wiring in the United States is 14-gauge copper wire which has a radius of 813μm. What is the magnetic field strength inside the wire, halfway between the center and the outside edge, when it is carrying a typical household current of 10A?336views
Multiple ChoiceA wire near the equator carries a current perpendicular to the Earth's magnetic field of 50μT in a location where the field is parallel to the ground and points straight north. Assuming it was of correct magnitude, what direction should the current be in to levitate the wire?343views1rank
Multiple ChoiceA wire near the equator carries a current perpendicular to the Earth's magnetic field of 50μT in a location where the field is parallel to the ground and points straight north. The wire has a mass per length of 5.9g/m. What magnitude of current in the wire could balance it against the force of gravity? (This example is not very realistic. The mass per length given would be reasonable for a very thin wire which could not handle this large of a current for very long.)242views
Textbook QuestionCurrents in dc transmission lines can be 100 A or higher. Some people are concerned that the electromagnetic fields from such lines near their homes could pose health dangers. For a line that has current 150 A and a height of 8.0 m above the ground, what magnetic field does the line produce at ground level? Express your answer in teslas and as a percentage of the earth's magnetic field, which is 0.50 G. Is this value cause for worry?921views
Textbook QuestionAn electromagnetic rail gun uses magnetic forces to launch projectiles. FIGURE P29.76 shows a 10-cm-long, 10 g metal wire that can slide without friction along 1.0-m-long horizontal rails. The rails are connected to a 300 V source, and a 0.10 T magnetic field fills the space between the rails. Each rail has linear resistivity ⋋ = 0.10 Ω/m, which means that the resistance is ⋋ multiplied by the length of rail through which current flows. Assume that the sliding wire and the left end, where the voltage source is, have zero resistance. The wire is initially placed at x₀ = 5.0 cm then the switch is closed. What is the wire's speed as it leaves the rails?135views
Textbook QuestionA 10 A current is charging a 1.0-cm-diameter parallel-plate capacitor. b. What is the magnetic field strength at a point 2.0 mm radially from the center of the capacitor?105views
Textbook Question(I) Jumper cables used to start a stalled vehicle often carry a 65-A current. How strong is the magnetic field 5.0 cm from one cable? Compare to the Earth’s magnetic field . (5.0 x 10⁻⁵ T) .80views
Textbook QuestionA continuous straight stream of protons passes a given point in space at a rate of 2.5 x 10⁹ protons/s. What magnetic field do they produce 1.8 m from the beam?76views
Textbook Question(I) Determine the magnitude and direction of the force between two long parallel wires 35 m long and 4.0 cm apart, each carrying 35 A in the same direction.75views
Textbook Question(II) A dc power line carries a current of 85 A west along the tops of 8.5-m-high poles. (a) What is the magnitude and direction of the magnetic field produced by this wire at the ground directly below? How does this compare with the Earth’s field of about ½G ? (b) Where would the current’s magnetic field cancel the Earth’s field? 23views
Textbook Question(II) Two long straight wires each carry a dc current I out of the page toward the viewer, Fig. 28–38. Indicate, with appropriate arrows, the direction of B (→ above B) at each of the points 1 to 6 in the plane of the page. State if the field is zero at any of the points.<IMAGE>12views
Textbook Question(II) Two long wires are oriented so that they are perpendicular to each other. At their closest, they are 20.0 cm apart (Fig. 28–42). What is the magnitude of the magnetic field at a point midway between them if the top one carries a current of 18.0 A and the bottom one carries 12.0 A?<IMAGE>2views
Textbook QuestionTwo long straight aluminum wires, each of diameter 0.42 mm, carry the same current but in opposite directions. They are suspended by 0.50-m-long strings as shown in Fig. 28–66. If the suspension strings make an angle of 3.0° with the vertical and are hanging freely, what is the current in the wires?<IMAGE>12views
Textbook Question(II) In Fig. 28–36, a long straight wire carries current I out of the page toward you. Indicate, with appropriate arrows, the direction and (relative) magnitude of B (→ above B) at each of the points C, D, and E in the plane of the page. <IMAGE> 13views
Textbook QuestionA long horizontal wire carries a current of 42 A. A second wire, made of 1.00-mm-diameter copper wire and parallel to the first, is kept in suspension magnetically 5.0 cm below (Fig. 28–60). (a) Determine the magnitude and direction of the current in the lower wire. (b) Is the lower wire in stable equilibrium? (c) Repeat parts (a) and (b) if the second wire is suspended 5.0 cm above the first due to the first’s magnetic field.<IMAGE> 4views
Textbook Question(II) Consider a straight section of wire of length d, as in Fig. 28–51, which carries a current I. (a) Show that the magnetic field at a point P a distance 𝑅 from the wire along its perpendicular bisector is B = (μ₀I / 2πR) ( d / (d² + 4R²) ¹/² (b) Show that this is consistent with Example 28–10 for an infinite wire. <IMAGE> 2views
Textbook Question(II) Two long parallel wires 8.20 cm apart carry 19.5-A dc currents in the same direction. Determine the magnetic field vector at a point P, 12.0 cm from one wire and 13.0 cm from the other. See Fig. 28–43. [Hint: Use the law of cosines. See Appendix A or inside rear cover.]<IMAGE> 1views
Textbook QuestionDetermine the magnetic field at a point P due to a very long wire with a square bend as shown in Fig. 28–63. The point P is halfway between the two corners. <IMAGE>1views