2) The situation is the same as in problem #1, but now there is friction between block 1 and the table. The coefficient of kinetic friction between the table and block 1 is µ = 0.20. a) Assuming that block 1 is sliding to the right (toward the pulley), find the acceleration of block 1. (2.4 m/s) b) Assuming that block 1 is sliding to the right (toward the pulley), find the tension in the string. (9.6 N) c) Sarah repeats this experiment but she gives block 1 a push to the left, so now it is sliding to the left (away from the pulley). Find the acceleration of block 1 (after Sarah has stopped pushing it but while it is still sliding to the left). (4.9 m/s) d) As above in part c, block 1 is sliding to the left (away from the pulley). Find the tension in the string (after Sarah has stopped pushing it). (6.4 N) %3D

Solve the problem number 2 in Newton's 2nd Law of Motion.

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1) A block (block 2) of mass m2 = 1.3 kg hangs from the end of a (massless) string which runs over a (massless frictionless) pulley. The other end of the string is connected to another block (block 1) of mass m, = 2.2 kg on a horizontal frictionless table. The situation is shown below. M1 M,

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2) The situation is the same as in problem #1, but now there is friction between block1 and the table. The coefficient of kinetic friction between the table and block 1 is µ = 0.20. a) Assuming that block 1 is sliding to the right (toward the pulley), find the acceleration of block 1. (2.4 m/s) b) Assuming that block 1 is sliding to the right (toward the pulley), find the tension in the string. (9.6 N) c) Sarah repeats this experiment but she gives block 1 a push to the left, so now it is sliding to the left (away from the pulley). Find the acceleration of block 1 (after Sarah has stopped pushing it but while it is still sliding to the left). (4.9 m/s²) d) As above in part c, block 1 is sliding to the left (away from the pulley). Find the tension in the string (after Sarah has stopped pushing it). (6.4 N)