5. In the figure shown, m = 6.00 kg and m2 = 7.00 kg. The angle of the incline is 0-30.0 degrees. The masses are released from rest. The diagram is not to scale. Disregard the mass or any friction in the pulley. 0) If the incline is frictionless: The blocks are released from rest. Which way, if any, do they move? Justify your answer. A) First: Frictionless surface. Draw the FBDS of each object. Derive algorithms for the acceleration of the blocks and the tension in the strings between them if the surface is frictionless in terms of the variables m, m,,0,g. Box them. Then put the values in, with units, and find numerical values to 3 sig figs. Box it. B) Repeat part A if the coefficient of kinetic friction between the block and the incline is = 0.15. Redo the FBD for the mass on the incline. C) What coefficient of kinetic friction would allow the blocks to move with a constant speed? Justify your answer.

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5. In the figure shown, mị = 6.00 kg and m2 = 7.00 kg. The angle of the incline is 0=30.0 degrees. The masses are released from rest. The diagram is not to scale. Disregard the mass or any friction in the pulley. 0) If the incline is frictionless: The blocks are released from rest. Which way, if any, do they move? Justify your answer. A) First: Frictionless surface. Draw the FBDS of each object. Derive algorithms for the acceleration of the blocks and the tension in the strings between them if the surface is frictionless in terms of the variables m, ,m,,0,g. Box them. Then put the values in, with units, and find numerical values to 3 sig figs. Box it. B) Repeat part A if the coefficient of kinetic friction between the block and the incline is µ = 0.15. Redo the FBD for the mass on the incline. C) What coefficient of kinetic friction would allow the blocks to move with a constant speed? Justify your answer.