yes
Yes it does.
It applies to both moving and non-moving objects.
It either keeps it still on the ground or stable as it's moving, but I'm not Stephen Hawking...
why are some objects faster than other
Newton's laws of motion apply here: things only change velocity when a force is acting upon them. While objects that are moving have (potential) kinetic energy, no extra energy is required to keep them moving: energy would be required to change their motion.
Yes it does.
It applies to both moving and non-moving objects.
All objects, whether moving or not.
It either keeps it still on the ground or stable as it's moving, but I'm not Stephen Hawking...
yes, the physics of inertia apply everywhere that inertia will be
the inertia is the force at wich an object is moving the heavier the object the further it will travel i think could be wrong but what do you think
The law of inertia applies to all physical objects.
Because of inertia. Stuff that is moving wants to keep moving. When the bike can't go forward, it'll try to topple forward instead.
gravity and friction along with inertia
Inertia is a fundamental property of all objects having mass. Mass resists the change in motion. Inertia applies to both the states of a body i.e., body at rest and at motion. Inertia is applicable to all objects in everyday life. For example " your body will continue to move forward because of inertia, when suddenly brake are applied during driving" Inertia is generally given by Newton's first law of motion, which is also called as "the law of inertia". This law states that an object will remain at rest or in uniform motion in a straight line unless acted upon by an external force. The more massive an object is, the greater will be its inertia, meaning that s it will require more force to change its state of motion.
Yes, if you apply it to every individual particle, or use integration.However, for practical calculations, it is often convenient to consider rotary motion separately. There is a rotational equivalent of Newton's Second Law (force = mass x acceleration), where you replace the force with a torque, the mass with the moment of inertia, and the acceleration with angular acceleration.The moment of inertia for objects of different forms are calculated through integration.Yes, if you apply it to every individual particle, or use integration.However, for practical calculations, it is often convenient to consider rotary motion separately. There is a rotational equivalent of Newton's Second Law (force = mass x acceleration), where you replace the force with a torque, the mass with the moment of inertia, and the acceleration with angular acceleration.The moment of inertia for objects of different forms are calculated through integration.Yes, if you apply it to every individual particle, or use integration.However, for practical calculations, it is often convenient to consider rotary motion separately. There is a rotational equivalent of Newton's Second Law (force = mass x acceleration), where you replace the force with a torque, the mass with the moment of inertia, and the acceleration with angular acceleration.The moment of inertia for objects of different forms are calculated through integration.Yes, if you apply it to every individual particle, or use integration.However, for practical calculations, it is often convenient to consider rotary motion separately. There is a rotational equivalent of Newton's Second Law (force = mass x acceleration), where you replace the force with a torque, the mass with the moment of inertia, and the acceleration with angular acceleration.The moment of inertia for objects of different forms are calculated through integration.
There are lots of ways inertia is applied to motocross. I will start this off, add things as you think of them. First off, the definition of inertia is the resistance of an object to a change in its state of motion. (1) A heavier flywheel carries speed farther, but is also harder to slow down than a light one.