Use the following constants if necessary. Coulomb constant, k = 8.987 x 10° N - m² /C². Vacuum permitivity, eo = 8.854 × 10-12 F/m. Magnetic Permeability of vacuum, Ho = 12.566370614356 x 10-7 H/m. Magnitude of the Charge of one electron, e = -1.60217662 x 10-19 CMass of one electron, m, = 9.10938356 x 10-31 kgUnless specified otherwise, each symbol carries their usual meaning. For example, µCmeans microcoulomb I In the figure the blue region represents a magnetic field B1 = 3.3 Tand the green region represents a magnetic field B2 = 6.0TA particle with charge q= 4.4 µG mass m = 0.065 granand velocity v = 35 m/savels toward the blue region as shown in the figure. c)Calculate the angular frequency of the particle when it is in the blue and when it is in the green region. What will happen to the angular frequency in the blue region if we double the velocity of the particle?

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Use the following constants if necessary. Coulomb constant, k = 8.987 × 10° N · m² /C². Vacuum permitivity, €o = 8.854 × 10-12 F/m. Magnetic Permeability of vacuum, lo = 12.566370614356 × 10-7 H/m. Magnitude of the Charge of one electron, e = -1.60217662 × 10-19 CMass of one electron, me = 9.10938356 × 10-31 kgunless specified otherwise, each symbol carries their usual meaning. For example, µC means micro coulomb In the figure the blue region represents a magnetic field B1 = 3.3 Tand the green region represents a magnetic field B2 = 6.0TA particle with charge q= 4.4 µG mass m = 0.065 granand velocity v = 35 m/savels toward the blue region as shown in the figure. c)Calculate the angular frequency of the particle when it is in the blue and when it is in the green region. What will happen to the angular frequency in the blue region if we double the velocity of the particle? angular frequency in blue region