Wiki User
β 14y agoWhether the object is dropped, thrown downwards, thrown upwards, or thrown horizontally,
its downward acceleration is the same 9.8 meters per second2.
If it's thrown downwards, however, its speed at any instant is greater than the speed at the same
instant would be if it had only been dropped, since it has some speed before the acceleration begins.
Wiki User
β 14y agoThe object will have the same acceleration of 9.8 meters per second squared whether you drop it or throw it downward. The initial velocity from throwing it will affect its overall velocity as it falls, but the acceleration due to gravity remains constant.
If you throw an object downward, its acceleration will be greater than 9.8 meters per second squared because you are adding to the acceleration due to gravity. The initial velocity from the throw adds to the gravitational acceleration, resulting in a faster overall acceleration downward.
When a skydiver is accelerating downward, the forces are unbalanced. The force of gravity acting downward on the skydiver is greater than the air resistance force pushing upward, causing the skydiver to accelerate downward.
No, in a vacuum or free-fall scenario, the acceleration due to gravity (g) is the maximum downward acceleration an object can experience. Any object falling under gravity without air resistance will have an acceleration equal to g (approximately 9.81 m/s^2).
When an elevator accelerates downward, the person inside will experience a greater force pushing them upward that is greater than their actual weight, making them feel lighter. This sensation is due to the interplay of different forces acting on the person in relation to the acceleration of the elevator.
To give an object a greater acceleration, you can either apply a greater force on the object or reduce its mass. Increasing the force acting on the object will accelerate it more, while reducing its mass will also result in a greater acceleration for the same force applied.
If you throw an object downward, its acceleration will be greater than 9.8 meters per second squared because you are adding to the acceleration due to gravity. The initial velocity from the throw adds to the gravitational acceleration, resulting in a faster overall acceleration downward.
When a skydiver is accelerating downward, the forces are unbalanced. The force of gravity acting downward on the skydiver is greater than the air resistance force pushing upward, causing the skydiver to accelerate downward.
No, in a vacuum or free-fall scenario, the acceleration due to gravity (g) is the maximum downward acceleration an object can experience. Any object falling under gravity without air resistance will have an acceleration equal to g (approximately 9.81 m/s^2).
When an elevator accelerates downward, the person inside will experience a greater force pushing them upward that is greater than their actual weight, making them feel lighter. This sensation is due to the interplay of different forces acting on the person in relation to the acceleration of the elevator.
To give an object a greater acceleration, you can either apply a greater force on the object or reduce its mass. Increasing the force acting on the object will accelerate it more, while reducing its mass will also result in a greater acceleration for the same force applied.
If the acceleration of a body is greater than the acceleration due to gravity, the body will start moving upward against the force of gravity. It may continue to accelerate if the net force acting on the body is greater than the force of gravity.
The acceleration will be in the direction of the net force.
Yes, an object with zero velocity can have an acceleration that is greater than zero if there is a change in its velocity over time. Acceleration is the rate of change of velocity, so even if the object starts with zero velocity, it can still accelerate if its velocity increases or decreases.
The measure of a body's resistance to acceleration is its inertia, which is proportional to its mass. The greater the mass of an object, the more force is needed to accelerate it.
Whenna given force is applied ,an oobject with greater mass will accelerate less
The tension can be greater than gravity when the elevator is accelerating downwards, causing a net force that exceeds the force of gravity acting on the elevator. This creates a situation where the tension in the elevator cable is greater than the force of gravity, allowing the elevator to move downwards.
The force required to accelerate an object is directly proportional to its mass, which is a measure of its inertia. Inertia is the resistance of an object to changes in its motion, so the greater the mass (inertia) of an object, the greater the force needed to accelerate it.