Moazin Khatri said:Yes I was talking about the over all CoM's movement.
But in the rotating case my nudge has given the pen a spin and some energy consequently. So won't this be a violation of the conservation of energy? Because if, in both cases, the pens have equal linear momentum thus equal kinetic energy due to their forward velocity but only in the rotatory case it also has a kinetic energy due to the spin...
Obviously the energy is given by my nudge. But suppose I give equal nudges. Or same force for the same period of time.PeroK said:The pen's initial kinetic energy is 0 in both cases, so energy isn't conserved in either case.
Moazin Khatri said:Obviously the energy is given by my nudge. But suppose I give equal nudges. Or same force for the same period of time.
Prannu said:Wait a minute, if the pen is in a zero-g environment, there won't be any torque on the pen (you need two forces that are acting at different parts of the pen to actually start the rotation).
Moazin Khatri said:Obviously the energy is given by my nudge. But suppose I give equal nudges. Or same force for the same period of time.
Thanks for your hint and advice. Yes I am already seeing it. I'll do a complete analysis and post it here for you to check it :) Thanks alotPeroK said:Here's a hint. If you think about an impulse as a instantaneous spike, it's difficult to see what's happening. Instead, imagine you apply a modest force for 1-2 seconds. Now, compare the two cases where you apply the force to the CM and to one end. You will notice significant differences in what happens. For example, in the second case, you'll have to make a decision about how you are going to continue to apply the force once the pen starts moving (and rotating).
Prannu said:Going with your first example PeroK, if a pen was on a flat surface, then the only reason why it rotates is because friction from the ground (acting at the CM) couples with the flick of your hand at a place that is not the CM. So if the pen was on a surface with 0 friction, the torque would be zero (unless I'm forgetting something here).
You cannot do this experiment reliably on a pen on a table. The imparted energy and the imparted momentum are very different concepts. The answers you have gotten have been based on your initial assumption of constant force. If you have a constant force for a fixed amount of time the imparted momentum is going to be the same, but the imparted energy is not. The work done is proportional to the force times the displacement, not force times time, and the displacement in the different cases is going to be different. When you do your pen experiment you will have serious trouble controlling that you are actually giving the same force during the same time.Moazin Khatri said:@PeroK
Case 1 => Force applied at the center
I apply a force at the CoM of the pen. The impulse lasts about 1 second and the pen goes off in a straight line with no spin at all.
Case 2 => Force at tip
I'm assuming that Newton's laws can be applied to any object with any shape or size and at any location.
I might apply the same force in this case but the impulse time will be short. The reason is my finger's direction will be a straight line and the pen will rotate and eventually miss my finger in about half of a second or maybe even less. If I apply F=dP/dt here I can easily see that in this case the pen's final velocity is going to be very low because the impulse time was very less compared to the first case.
I also exerted a variable torque in this case and due to that torque the pen will have a spin as well. Variable because of changing angle.
I did this experiment on a table and also noticed that the closer you nudge to the CoM the more linear momentum and the less angular momentum you give. The reason is because the closer you are the more impulse time you get and so you transfer more linear momentum. While the torque becomes less.
So basically both cases aren't identical at all and due to that my first question becomes meaningless.
Please correct me wherever I am wrong. Thanks
The center of mass is the point where an object's mass is evenly distributed. It is important because it allows us to simplify the analysis of an object's motion and understand how forces act on it.
Forces exerted somewhere other than the center of mass are known as external forces. These forces can cause an object to rotate or move in a different direction than its center of mass.
When external forces act on an object, they cause it to rotate or move in a different direction. This can result in changes in the object's velocity, acceleration, and overall motion.
Examples of forces exerted somewhere other than the center of mass include friction, tension, and gravity acting at a distance. These forces can cause an object to rotate or move in a different direction than its center of mass.
Scientists use mathematical equations and principles of physics to analyze and understand the effects of external forces on an object's motion. They also conduct experiments to observe and measure these forces in action.