Use the following constants if necessary. Coulomb constant, k=8.987×10^9N•M2/C2. Vacuum permittivity, co=8.854×10^-12F/m. Magnetic Permeability of vacuum, µo=12.566370614356×10^_7H/m. Magnitude of the Charge of one electron, e=-1.60217662×10^-19C. Mass of one electron, me=9.10938356×10^-31kg. Unless specified otherwise, each symbol carries their usual meaning. For example, µC means microcoulomb. .Y R R/2 ↑ : d A single current-carrying circular loop of radius R=5.7cm is placed next to a long straight wire as shown in Figure. A current i1=-8.8A is passing through the wire towards right. At a certain moment an electron is moving at a velocity v =590.0j^m/s toward the center of the circular wire. At the instant shown in figure, the electron's distance from the wire is d=6.9cm. The z axis points out of the page in the coordinate system shown in the figure which is represented by the circle with a dot inside. a) Compute the magnitude of the magnetic field at the center c due to the current passing through the straight wire b) In unit vector notation, find the magnetic force on the electron due to the current passing through the straight wire. c) Calculate the magnitude and direction of the current to the circular wire to produce zero magnetic field at its center c. Consider counterclockwise circulation of current as positive. (Please state the value of the current with sign) ON
Use the following constants if necessary. Coulomb constant, k=8.987×10^9N•M2/C2. Vacuum permittivity, co=8.854×10^-12F/m. Magnetic Permeability of vacuum, µo=12.566370614356×10^_7H/m. Magnitude of the Charge of one electron, e=-1.60217662×10^-19C. Mass of one electron, me=9.10938356×10^-31kg. Unless specified otherwise, each symbol carries their usual meaning. For example, µC means microcoulomb. .Y R R/2 ↑ : d A single current-carrying circular loop of radius R=5.7cm is placed next to a long straight wire as shown in Figure. A current i1=-8.8A is passing through the wire towards right. At a certain moment an electron is moving at a velocity v =590.0j^m/s toward the center of the circular wire. At the instant shown in figure, the electron's distance from the wire is d=6.9cm. The z axis points out of the page in the coordinate system shown in the figure which is represented by the circle with a dot inside. a) Compute the magnitude of the magnetic field at the center c due to the current passing through the straight wire b) In unit vector notation, find the magnetic force on the electron due to the current passing through the straight wire. c) Calculate the magnitude and direction of the current to the circular wire to produce zero magnetic field at its center c. Consider counterclockwise circulation of current as positive. (Please state the value of the current with sign) ON
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