more mass in motion= higher stored energy, requiring more forces (friction, gravity) to still the momentum of the heavier object.
Friction between the pendulum and the air or the supporting point, as well as friction in the pendulum's pivot point, can cause it to slow down and stop. Additionally, if the pendulum loses energy due to collisions or interactions with other objects, it will gradually slow down and eventually come to a stop.
To make the lighter ball harder to stop than the heavier ball, you can increase the lighter ball's velocity or decrease the heavier ball's velocity. This strategy exploits the kinetic energy of the moving objects, as the faster-moving lighter ball will have more kinetic energy that needs to be dissipated upon impact, making it harder to stop. Additionally, you can manipulate the surface material or shape of the balls to affect their friction and bounce properties, impacting how quickly they come to a stop.
The pendulum swinging in water will come to a complete stop faster than the one swinging in air due to the increased resistance from the water. Water creates more drag force on the pendulum, which dampens its motion more quickly. The presence of water molecules interacting with the pendulum's movements increases the dissipation of energy, leading to a faster decrease in swinging time.
It is harder to stop a heavy object because it has more inertia, which means it resists changes in its state of motion. More force is required to stop a heavy object compared to a lighter one due to its mass.
You can make a pendulum stop by simply stopping its movement with your hand or by reducing the amplitude of its swing gradually over time. Additionally, you can use friction or air resistance to slow down the pendulum and make it come to a stop.
Friction between the pendulum and the air or the supporting point, as well as friction in the pendulum's pivot point, can cause it to slow down and stop. Additionally, if the pendulum loses energy due to collisions or interactions with other objects, it will gradually slow down and eventually come to a stop.
To make the lighter ball harder to stop than the heavier ball, you can increase the lighter ball's velocity or decrease the heavier ball's velocity. This strategy exploits the kinetic energy of the moving objects, as the faster-moving lighter ball will have more kinetic energy that needs to be dissipated upon impact, making it harder to stop. Additionally, you can manipulate the surface material or shape of the balls to affect their friction and bounce properties, impacting how quickly they come to a stop.
The pendulum swinging in water will come to a complete stop faster than the one swinging in air due to the increased resistance from the water. Water creates more drag force on the pendulum, which dampens its motion more quickly. The presence of water molecules interacting with the pendulum's movements increases the dissipation of energy, leading to a faster decrease in swinging time.
The pendulum will take more time in air to stop completely in comparision with water
It is harder to stop a heavy object because it has more inertia, which means it resists changes in its state of motion. More force is required to stop a heavy object compared to a lighter one due to its mass.
You can make a pendulum stop by simply stopping its movement with your hand or by reducing the amplitude of its swing gradually over time. Additionally, you can use friction or air resistance to slow down the pendulum and make it come to a stop.
Gravity doesn't make a pendulum stop. Air resistance and friction in the pivot are the things that rob its energy. If you could eliminate those and leave it all up to gravity, the pendulum would never stop.
In a pendulum, potential energy is converted to kinetic energy as it swings back and forth. Friction and air resistance gradually dissipate the kinetic energy, causing the pendulum to eventually stop swinging.
Yes, a pendulum will eventually stop swinging due to factors such as air resistance and friction, which gradually slow down its motion.
A pendulum will eventually come to a stop due to air resistance and friction, which absorb the pendulum's energy over time. The rate at which the pendulum's motion slows down depends on the amount of resistance it encounters and the initial energy imparted to it.
Because of both air resistance and gravity that pulls the pendulum down.
An extreme point on a pendulum swing is the highest or lowest point the pendulum reaches during its motion. At this point, the pendulum temporarily comes to a stop before changing direction.