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A small stone A of mass 3m is attached to one end of a string - Edexcel - A-Level Maths Mechanics - Question 2 - 2021 - Paper 1

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A small stone A of mass 3m is attached to one end of a string. A small stone B of mass m is attached to the other end of the string. Initially A is held at rest on a... show full transcript

Worked Solution & Example Answer:A small stone A of mass 3m is attached to one end of a string - Edexcel - A-Level Maths Mechanics - Question 2 - 2021 - Paper 1

Step 1

Write down an equation of motion for A

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Answer

To derive the equation of motion for stone A, we consider the forces acting on it along the incline. The forces include the gravitational force component acting down the incline and the tension in the string. The equation can be expressed as:

3mgsin(α)FT=3ma3mg \sin(\alpha) - F - T = 3ma

where:

  • FF is the frictional force, given by F=16RF = \frac{1}{6} R.
  • RR is the normal reaction force calculated as R=3mgcos(α)R = 3mg \cos(\alpha). Finally,
T=3mgsin(α)F3maT = 3mg \sin(\alpha) - F - 3ma

Step 2

Show that the acceleration of A is \( \frac{1}{10} g \)

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Answer

From the equation established earlier, we can substitute the values of friction and normal reaction force:

  1. Substitute F=16RF = \frac{1}{6} R into the equation of motion:
T=3mgsin(α)16R3maT = 3mg \sin(\alpha) - \frac{1}{6} R - 3ma
  1. Since R=3mgcos(α)R = 3mg \cos(\alpha), we replace it in the equation:
T=3mgsin(α)16(3mgcos(α))3maT = 3mg \sin(\alpha) - \frac{1}{6} (3mg \cos(\alpha)) - 3ma
  1. Substituting sin(α)\sin(\alpha) and cos(α)\cos(\alpha) derived from tan(α)=34\tan(\alpha) = \frac{3}{4}, we find:
sin(α)=35,cos(α)=45\sin(\alpha) = \frac{3}{5}, \quad \cos(\alpha) = \frac{4}{5}
  1. Thus,
T=3mg(35)16(3mg(45))3maT = 3mg \left( \frac{3}{5} \right) - \frac{1}{6} (3mg \left( \frac{4}{5} \right)) - 3ma
  1. This leads to:
a=110ga = \frac{1}{10} g

Step 3

Sketch a velocity-time graph for the motion of B

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Answer

The velocity-time graph for the motion of stone B can be sketched based on the principles of constant acceleration.

  • Initially, stone B is at rest. When stone A is released, stone B begins to move downward as A moves down the plane.
  • Since the system is set up in such a way that the motion of A influences B, we can describe the velocity of B steadily increasing.
  • The graph is a straight line starting from the origin, indicating constant acceleration. The slope of this line represents the acceleration ( ( \frac{1}{10} g )).

It will show time on the x-axis and velocity on the y-axis, with a linear increase until the moment just before B reaches the pulley.

Step 4

State how this would affect the working in part (b)

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Answer

The fact that the string is not light introduces a significant alteration to the system. The tension in the string would vary depending on the weight of the stones and the acceleration of the entire system. Stone B would experience a different tension as compared to A due to its different mass and position in the pulley system. This would affect the derived acceleration formula of A in part (b) as it becomes dependent on these tension values, leading to potential discrepancies in assuming a constant acceleration for both stones.

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