Correct

Yes, the tension in the string is equal to 2.35 N. The snapshot above shows the system at an instant when it is in motion.

Solution

Plan It. Apply Newton's second law to the two blocks separately. This will give two equations for two unknowns: the tension T and the magnitude a of the acceleration of the blocks. (Both blocks will have accelerations of the same magnitude because the string is assumed to not stretch.) Note that the magnitudes T1 and T2 of the forces exerted by the string on blocks 1 and 2, respectively, are equal to the tension T: T = T1 = T2. The two equations for T and a can be solved.

Setup

     block 1 (x-direction):     T = m1a     (1)

     block 2 (y-direction):     m2g - T = m2a.    (2)

Solution. We are interested in T and must eliminate a from (1) and (2). Multiplying both sides of (1) by m2 and multiplying both sides of (2) by m1 gives

                     m2T = m1m2a    (3)
and
                     m1m2g - m1T = m1m2a.    (4)

Subtracting (4) from (3) gives

                     m2 T - (m1 m2g - m1T) = 0    (5)
whence
                     m1T + m2 T = m1 m2g    (6)
whence
                     T = [m1 m2 /( m1+ m2)] g .    (7)

Substituting the given mass values gives for the tension T in the string and the magnitudes of the forces exerted by the string on the two blocks:

                 T = T1 = T2 = [0.6x0.4/(0.6+0.4)] x 9.8 = 0.24 x 9.8 = 2.35 N .    (8)

If one has already found the magnitude of the acceleration, 3.92 m/s2, it is very easy to get the tension by substituting into equation (1). Thus,

                 T = m1a = 0.6 x 3.92 = 2.35 N.     (9)

Think About It.

  1. The final expression (7) for the tension is dimensionally correct. The numerator of the fraction is a mass2 and the denominator a mass. Thus, the ratio of the two is a mass. Multiplied by g, which has the units of acceleration, gives a force because mass times acceleration is a force. Thus, equation (7) is correct dimensionally.
  2. Expression (7) is consistent with Answer (c) to Question 1 because it can be written

                 T = m1 /( m1+ m2) m2g.    (10)

    Thus,    T < m2g    since    m1 /( m1+ m2) < 1.

  3. When the mass m2 goes to zero, one would expect the tension T to go to zero as well. Expression (7) is consistent with this.