- #1
ConfusedMonkey
- 42
- 15
This is an example given in my textbook:
"On a frictionless horizontal surface, you push with a force ##\vec{F}## on a book of mass ##m_1## that in turn pushes on a book with a mass ##m_2##. What force does the second book exert on the first?"
First they calculate the acceleration of book 2. This is how they do it:
"The total mass of the two blocks is ##m_1 + m_2##, and the net force applied to the combination is ##\vec{F}##.
I want to make sure that I understand correctly why the net force is ##\vec{F}##. Here is my explanation:
I originally push book 1 with a force of ##\vec{F}##. Because of this, book 1 starts to accelerate in the direction of my push and thus exerts a force, say ##\vec{F_{12}}## on book 2, and by Newton's third law, book 2 then exerts a force, say ##\vec{F_{21}}## on book 1. Thus the net force of the system is ##\vec{F} + \vec{F_{12}} + \vec{F_{21}} = \vec{F} + \vec{F_{12}} - \vec{F_{12}} = \vec{F}##. Is my reasoning correct?
"On a frictionless horizontal surface, you push with a force ##\vec{F}## on a book of mass ##m_1## that in turn pushes on a book with a mass ##m_2##. What force does the second book exert on the first?"
First they calculate the acceleration of book 2. This is how they do it:
"The total mass of the two blocks is ##m_1 + m_2##, and the net force applied to the combination is ##\vec{F}##.
I want to make sure that I understand correctly why the net force is ##\vec{F}##. Here is my explanation:
I originally push book 1 with a force of ##\vec{F}##. Because of this, book 1 starts to accelerate in the direction of my push and thus exerts a force, say ##\vec{F_{12}}## on book 2, and by Newton's third law, book 2 then exerts a force, say ##\vec{F_{21}}## on book 1. Thus the net force of the system is ##\vec{F} + \vec{F_{12}} + \vec{F_{21}} = \vec{F} + \vec{F_{12}} - \vec{F_{12}} = \vec{F}##. Is my reasoning correct?
Last edited: