Answer Happy

-In Part III of this experiment, is it reasonable to assume that
the strength of the magnetic field depends directly on the number
of magnets? Why? (Why not? Refer to your graph.)
- In the same part as in previous
question, what would happen if we reversed the polarity of one of
the magnets? (You can assume that you have 4 magnets in N-S
configuration and the fifth one is in S-N configuration.)
-Write down the formula for the magnetic force on a current
carrying wire in both vector form and scalar form. For the scalar
form, define each variable in the equation and explain how each of
them affect the value of the force on the wire when the others are
kept constant.
-Compare your results with your answers regarding each variable
for the second question in the previous question. Do your results
satisfy your initial comments? Why? (Why not?) What are the main
differences and causes for those differences?
Part III 5. Table 7.1 (In this part, the initial mass of magnet assembly is changing for each step) m0-157,28 g 9,807 m/s² I=2A L=1.2cm # of magnets Mass (g) when I Mass (g) when I Force (N) Change in mass (g) = 0 #0 1 97.1 97.2 2 109.0 109.25 3 120.9 121.0 4 133.45 133.26 157.58 5 157.68 * Do not forget the unit conversation and SHOW YOUR CALCULATION AT LEAST ONE DATASET (10 Pt.) 6. Draw a Force (N) vs "# of magnets" graph. | Part IV 7. Table 7.2 L=1.2cm I=1A mo.105.93...(initial mass of magnet assembly) Angle (0) Angle (0) Mass (g) Change in Force (N) Mass (g) Force (N) Change in Mass (g) Mass (g) 0 105,96 m-mo|= 0 105,96 |m-mo|= 20 105,96 m-mo= -20 105,98 m-mo= 40 106 m-mo= -40 105,85 m-mo= 60 106,05 m-mo -60 105,80 m-mo 80 -80 105,75 m-mo= 106,1 m-mo= 106,12 |m-mo|= 90 -90 105,72 m-mo= * Do not forget the unit conversation and SHOW YOUR CALCULATION AT LEAST ONE DATASET(10 Pt.) 8. [15 Pt.] Plot a Force (N) vs Angle (0) graph. Make sure the angle starts form -90 and ends at 90 degrees.