inertia
When you push on a wall, the wall exerts an equal and opposite force back on you, according to Newton's third law of motion. This reaction force is what gives you the feeling of the wall pushing back against you.
Yes, according to Newton's third law of motion, for every action, there is an equal and opposite reaction. When you push on a wall, the wall exerts an equal force back on you, which is why you can feel the resistance.
The equal and opposite reaction is the wall pushing back against you. When you hit the wall with a stick, the force you exert on the wall is transferred to you through the stick, causing the wall to push back with an equal force. The stick simply transmits this force between you and the wall.
The wall pushes back on you with an equal force of 100 N, as described by Newton's Third Law of Motion which states that for every action, there is an equal and opposite reaction.
When you push against a wall, the wall exerts an equal and opposite force back on you. When you jump off the ground, the ground pushes back on you with an equal force. When a car accelerates forward, the tires push backward on the ground, creating a forward motion.
inertia
static friction
When you push on a wall, the wall exerts an equal and opposite force back on you, according to Newton's third law of motion. This reaction force is what gives you the feeling of the wall pushing back against you.
Yes, according to Newton's third law of motion, for every action, there is an equal and opposite reaction. When you push on a wall, the wall exerts an equal force back on you, which is why you can feel the resistance.
The equal and opposite reaction is the wall pushing back against you. When you hit the wall with a stick, the force you exert on the wall is transferred to you through the stick, causing the wall to push back with an equal force. The stick simply transmits this force between you and the wall.
It pushes back with an equal force (10 N). If it can not, then it falls over.
An interaction requires a pair of forces acting on two separate objects. You can feel your fingers being pushed by your friends fingers. You also feel the same amount of force when you push on a wall and it pushes back on you. As a point of fact, you cannot push on the wall unless it pushes back on you.
The wall pushes back on you with an equal force of 100 N, as described by Newton's Third Law of Motion which states that for every action, there is an equal and opposite reaction.
An interaction requires a pair of forces acting on two separate objects. You can feel your fingers being pushed by your friends fingers. You also feel the same amount of force when you push on a wall and it pushes back on you. As a point of fact, you cannot push on the wall unless it pushes back on you.
When you push against a wall, the wall exerts an equal and opposite force back on you. When you jump off the ground, the ground pushes back on you with an equal force. When a car accelerates forward, the tires push backward on the ground, creating a forward motion.
An example of action-reaction pairs is when you push against a wall (action) and the wall pushes back against you with an equal force (reaction). Another example is when a rocket pushes gas downwards (action), causing the rocket to move upwards (reaction).
It's up to you. If you are a girl, it is entirely your choice whether you push her away or kiss back. If you are a boy, then obviously she's not a lesbian.