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Will a flat sheet of paper dropped from a height of 2 m accelerate at the same rate as piece of paper crumpled into a ball Why or why not?
Yes, both the flat sheet of paper and the crumpled paper ball will accelerate at the same rate due to gravity, regardless of their shapes. The acceleration due to gravity is a constant value for all objects near the surface of Earth.
Will a flat sheet of paper accelerate at the same rate as a crumpled paper?
In a vacuum, both a flat sheet of paper and a crumpled paper would accelerate at the same rate due to gravity. However, air resistance may affect the acceleration of a crumpled paper more than a flat sheet due to differences in surface area and shape, causing the crumpled paper to fall slower.
Is the force of gravity stronger on a crumpled piece of paper than on an identical piece of paper which has not been crumpled?
No, the force of gravity is the same for both the crumpled and non-crumpled pieces of paper. Gravity acts on all objects the same way, regardless of their shape or condition. The only factor that affects the force of gravity is the mass of the object.
Will a flat sheet sheet of paper dropped from a height of 2 m accelerate at the same rate as a piece of paper crumbled into a ball Why or why not?
Yes, both the flat sheet of paper and the crumpled ball of paper will accelerate at the same rate when dropped from a height of 2 m. This is because acceleration due to gravity is constant regardless of the shape or size of the object. The air resistance may have a small effect, but in this scenario, the difference is negligible.
What falls faster a crumpled ball of paper or a flat sheet of paper?
Assuming that both pieces of paper weigh the same, a crumpled piece falls faster in the presence of an atmosphere. In a vacuum, they would fall at the same speed due to the lack of wind resistence.
Will a flat sheet of paper dropped from a height of 2 m accelerate at the same rate as piece of paper crumpled into a ball Why or why not?
Yes, both the flat sheet of paper and the crumpled paper ball will accelerate at the same rate due to gravity, regardless of their shapes. The acceleration due to gravity is a constant value for all objects near the surface of Earth.
Will a flat sheet of paper accelerate at the same rate as a crumpled paper?
In a vacuum, both a flat sheet of paper and a crumpled paper would accelerate at the same rate due to gravity. However, air resistance may affect the acceleration of a crumpled paper more than a flat sheet due to differences in surface area and shape, causing the crumpled paper to fall slower.
Is the force of gravity stronger on a crumpled piece of paper than on an identical piece of paper which has not been crumpled?
No, the force of gravity is the same for both the crumpled and non-crumpled pieces of paper. Gravity acts on all objects the same way, regardless of their shape or condition. The only factor that affects the force of gravity is the mass of the object.
Will a flat sheet sheet of paper dropped from a height of 2 m accelerate at the same rate as a piece of paper crumbled into a ball Why or why not?
Yes, both the flat sheet of paper and the crumpled ball of paper will accelerate at the same rate when dropped from a height of 2 m. This is because acceleration due to gravity is constant regardless of the shape or size of the object. The air resistance may have a small effect, but in this scenario, the difference is negligible.
What falls faster a crumpled ball of paper or a flat sheet of paper?
Assuming that both pieces of paper weigh the same, a crumpled piece falls faster in the presence of an atmosphere. In a vacuum, they would fall at the same speed due to the lack of wind resistence.
Is it true or false when a crumpled piece of paper falls to the ground more quickly than a flat piece of paper becauseof gravity?
False, the gravity on the sheet of paper is the same regardless of its shape. However the crumpled sheet has less air resistance than the flat sheet allowing it to fall faster.
Which will fall first in vacuum paper or stone?
Depends on which one is dropped first. If they are both dropped at the same time, they will both reach the ground at the same time.
Why does a crumbled piece of paper hit the ground before a flat piece of paper?
The flat paper has more surface area, allowing it to catch more air and float. The crumpled paper on the other hand, does not, because it doesn't have as much surface area to spread the air out.
Would a crumple paper ball or rectangular shape paper reach the ground?
Both the crumpled paper ball and the rectangular shape paper would reach the ground at the same time when dropped from the same height in a vacuum. This is because in the absence of air resistance, all objects fall at the same rate due to gravity.
What will burn faster a crumpled paper or a flat one?
stone is faster than paper because it has more mass so more gravity include on it
Which fall faster coin or a crumpled paper?
This is a classic question. In a vacuum, both the the coin and the crumpled paper fall at the same rate due to the absence of air resistance.(Their acceleration being the same) However, in air, the relative air resistance on the paper is greater than on the coin.(relative, because the coin and the paper do not have the same mass, so the proportion of air resistance as compared to weight is the one relevant) So the acceleration of the paper decreases to zero more rapidly than the coin.(it will decrease to zero provided the objects are released from a sufficiently high point from the earth's surface). Thus, the coin will fall faster in air.
When dropped from the same height why does a flat sheet of paper fall more slowly than the same sheet when it is tightly crumpled into a ball?
A Crumpled sheet of paper falls faster than flat sheet because a flat sheet has a relatively greater exposed surface area and hence experiences more resistance from air or the medium in which it travels. Although an upward buoyant force acts on the flat sheet but it is negligible in magnitude and hence can be considered to be zero until and unless the calculations require a very high degree of accuracy such as experimenting with fundamentals of pure sciences. Patrick Stolz Physics Teachers Forum
