Use the following constants if necessary. Coulomb constant, k=8.987×109N⋅m2/C2. Vacuum permitivity, ϵ0=8.854×10−12F/m. Magnetic Permeability of vacuum, μ0=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

A current carrying wire(wire-1) with i1=14Amperes is placed at the origin on the Y-Z plane. Another current carrying wire(wire-2) with i2=14Amperes is placed l=11m distance apart on the Y-axis. The point P2 is l1=8m from the wire-1. P1(0,8,−13), P2(0,8,0) and the point P3(0,8,10) are on the same line. The direction of the current is given in the figure.

Step 1: Consider a wire-1 only. 

1. a)Calculate magnetic field at P1

x component, y component & z component

Calculate the magnetic field at P2

x component, y component & z component

Step 2:Consider both wires

1. b)Now what is the net magnetic field at pointP2?

x component, y component & z component

What is the Magnetic field at pointP3

x component, y component  & z component

Transcribed Image Text:

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, µo = 12.566370614356 × 10-7 H/m. Magnitude of the Charge of one electron, e = -1.60217662 × 10-19 C. Mass of one electron, me = 9.10938356 × 10-31 kg. Unless specified otherwise, each symbol carries their usual meaning. For example, µC means micro coulomb * P dz wire 1 wire 2 * Pi K.- l, - K.- l- A current carrying wire(wire-1) with i = 14 Amperes is placed at the origin on the Y-Z plane. Another current carrying wire(wire-2) with i2 = 14 Amperes is placed I = 11 m distance apart on the Y-axis. The point P, is l1 = 8 m from the wire-1. P (0, 8, – 13), P2 (0, 8,0) and the point P3 (0,8, 10) are on the same line. The direction of the current is given in the figure.