In the figure below each mass is 2.00 kg. (Figure 1) You may want to review (Page). For general problem-solving tips and strategies for this topic, you may want to view a Video Tutor Solution of Gravitational forces in a Cavendish balance. Figure B (a) 10 cm 40 cm- B (b) 10 cm 40 cm- > 1 of 1 Part A Find the magnitude of the net gravitational force on mass A due to masses B and C in the figure (a). ▼ View Available Hint(s) Hint 1. How to approach the problem You are asked to find the net gravitational force on mass A due to the other two masses. Since the gravitational force is a vector force, you can sum the vector force acting on mass A due to mass B and the vector force acting on mass A due to mass C to find the net force on mass A. Draw a sketch of figure (a). Since the masses all lie along a straight line, draw an axis to the right indicating a positive direction along this straight line. Draw arrows indicating the direction of the gravitational force on mass A due to each of the other masses separately. Note that the gravitational force is always attractive. You should be able define a sign for each of the two gravitational forces acting on mass A in relation to your axis. Use Newton's law of universal gravitation to find the magnitude of the gravitational forces. Then, sum the forces with the correct signs to find the resultant gravitational force and take the magnitude. Ο ΑΣΦ x Хь b √x vx F=2.56 10- 2.56.10-8 אז x K☑ 0 ? X X.10" ☑ N

Transcribed Image Text:

In the figure below each mass is 2.00 kg. (Figure 1) You may want to review (Page). For general problem-solving tips and strategies for this topic, you may want to view a Video Tutor Solution of Gravitational forces in a Cavendish balance. Figure B (a) 10 cm 40 cm- B (b) 10 cm 40 cm- > 1 of 1

Transcribed Image Text:

Part A Find the magnitude of the net gravitational force on mass A due to masses B and C in the figure (a). ▼ View Available Hint(s) Hint 1. How to approach the problem You are asked to find the net gravitational force on mass A due to the other two masses. Since the gravitational force is a vector force, you can sum the vector force acting on mass A due to mass B and the vector force acting on mass A due to mass C to find the net force on mass A. Draw a sketch of figure (a). Since the masses all lie along a straight line, draw an axis to the right indicating a positive direction along this straight line. Draw arrows indicating the direction of the gravitational force on mass A due to each of the other masses separately. Note that the gravitational force is always attractive. You should be able define a sign for each of the two gravitational forces acting on mass A in relation to your axis. Use Newton's law of universal gravitation to find the magnitude of the gravitational forces. Then, sum the forces with the correct signs to find the resultant gravitational force and take the magnitude. Ο ΑΣΦ x Хь b √x vx F=2.56 10- 2.56.10-8 אז x K☑ 0 ? X X.10" ☑ N