What Is the Mass of a Book Accelerating on a Wooden Table?

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AI Thread Summary
The discussion revolves around calculating the mass of a book accelerating on a wooden table, given a frictional force of 2.6N and an applied force of 2.8N. The net force acting on the book is determined by subtracting the frictional force from the applied force, resulting in a net force of 0.2N. Using Newton's second law (F=ma), the mass of the book is calculated by dividing the net force by the acceleration of 0.11 m/s, yielding a mass of 1.8 kg. The importance of considering the direction of forces in calculating net force is emphasized. This approach effectively demonstrates the relationship between force, mass, and acceleration in physics.
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Homework Statement


Because of a frictional force of 2.6N, a force of 2.8N must be applied to a textbook in order to slide it along the surface of a wooden table. The book accelerates at a rate of 0.11 m/s

a) What is the unbalanced force on the book?
b) What is the mass of the book?

Homework Equations



The Attempt at a Solution



The frictional force of 2.6 has anything to do with the equation F=ma to find the mass? If yes, what is the equation?
 
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rfurtado said:

The Attempt at a Solution



The frictional force of 2.6 has anything to do with the equation F=ma to find the mass? If yes, what is the equation?

Yes, it does, because 'F' in that equation refers to the NET force on the body (also referred to as the unbalanced force in your homework problem). To calculate the net force, you must consider the applied force and the frictional force, adding them together (taking into account their directions).
 
Oh ok. So you mean that I need to add (the regular addition or in any other way?) the frictional force which is 2.6 and the force of 2.8, and then finish with the regular equation to find the mass?
 
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No, obviously not just regular addition. Like I said before, you have to take into account the directions of the forces! The applied force is trying to move the textbook in one direction, eg. to the right. The frictional force is trying to oppose that motion (it points to the left). The two forces are *opposite*, so one of them partly balances out (ie cancels out) the other. The remaining part (which is the NET force acting on the object) is the only thing that is left to actually move the object. Since you know that the acceleration value given in the problem must be due to this "leftover" force, you can deduce the mass of the object.
 
Now I think I got it =) well, I did the equation and got .2N as the remaining force, then I did the regular equation to find the mass.

m= ? ========> m=f/a ==> m=.2/.11= 1.8 kg
a= .11 m/s
f= .2N
 
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