Why does mass affect acceleration?
inertia inertia inertia
the mass does affexct the velocity of acceleration
Yes. F/m=a mass is inverse to acceleration.
force is directly proportional to acceleration and acceleration is inversely proportional to mass of the body
increase in mass affects how much acceleration or force is needed to move that mass.
It does not affect its acceleration in a vacuum, that is, no air resistance. The acceleration s the acceleration of gravity which is constant
Force = mass x acceleration. The greater the force, the greater the acceleration
If you double the mass then the acceleration is halved, with the same force.
According to Newton's second law, force equals mass times acceleration.
Force and mass. Acceleration is force per unit of mass (a=f/m).
Force = mass x acceleration. This means that for more mass, you need more force. Also, if you want more acceleration, you need more force.
Force and mass. Acceleration is force per unit of mass (a=f/m)
Acceleration = Force/mass.
this equation might help force = mass * acceleration the more massive an object is the more force is required to accelerate it
Force accelerates stationary masses as acceleration a=f/m; theacceleration is inverse to the mass. The smaller the mass the larger the acceleration and the larger the mass the smaller the acceleration.
From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change. From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change. From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change. From the formula… Read More
It will reduce the acceleration in proportion to the increase in mass, from Newton's second law, F = ma.
The force acting upon the object as well as the mass of the object. Both will affect the acceleration of the object.
Change Near Earth, doubling the mass of an object will not affect how it gravitationally accelerates (ignoring air friction), but might affect how it accelerates across a pond of water (for the pond, the acceleration is probably not proportional to the mass).
Force affects an object by accelerating it. Newton's Second Law of Motion states that force = mass times acceleration. Solving for acceleration, you get acceleration = force divided by mass.
If it has more mass, it requires more effort - more force, really - to accelerate it. With a greater mass, the same force would result in less acceleration.
Force and mass. Isaac Newton's second law of motion tells us that force equals mass times acceleration.
Take a look at Newton's Second Law: F=ma (force = mass x acceleration). Solving for acceleration: a=F/m. In other words, if the force is the same, more mass will result in less acceleration, since the mass is in the denominator.
F = m * a Force equals mass times acceleration. As the mass increases the acceleration (rate of change of the speed) decreases.
ANY net force will cause an acceleration. If the force is reduced, there will be less acceleration, though.
It depends on the force. The acceleration due to gravity (for small objects) is essentially independent of mass, although air friction may be worse for very small objects. If, however, you have a constant force. F = MA Force = Mass * Acceleration. Divide each side by mass and you get: Acceleration = (Force / Mass) So, for constant force, the more mass an object has, the less acceleration. Or, you could say that for… Read More
The acceleration of an object is completely described and accounted for by the object's mass and the forces acting on it. Nothing else.
Yes. The force =mass x acceleration, f=ma. The larger the mass the larger the force.
Yes. Force= mass times acceleration if mass is large the force is large.
because u doing the same thing
Acceleration is proportional to the resultant force acting on a body fo constant mass. (Newton's second law)
The mass of the planet and the distance the object is from the planetary center. The greater the mass of the planet, the greater the acceleration due to gravity. The closer to the planetary center, the greater the acceleration due to gravity.
The greater the force the more acceleration there is. Force = Mass x Acceleration (Newton's Second Law) F = ma Where force is measured in Newtons, mass in kilograms and acceleration in metres per second. The larger the force on an object of a certain mass the greater will be its acceleration. force = mass x acceleration therefore if an objects force increases then it follows that the increase is due to an increase in… Read More
When a force is applied, mass and acceleration are inversely proportional. Newton's 2nd law, F=ma, says that if an equal force is applied to a larger mass, it will accelerate proportionally more slowly.
Newton's second law deals with mass and force as it relates to acceleration. Acceleration down the hill is the main part of skiing, which skiers can affect by changing their mass or the force they use to push themselves down the hill.
Well distance has barely any effect on it, but mass does since Force = acceleration x mass The acceleration in this case is always 9.81 m²/s (= Gravity), so the force actually depends on the mass only.
Velocity, mass, forces, acceleration, slope, etc.
-- the object's mass -- the net force acting on it
When an object is falling in a gravity field, its mass does not affect its acceleration. If under the influence of friction then it takes more energy to accelerate it the larger mass it has, here on Earth. The larger the mass the more potential it has to do work if it is above the surface of the earth than a smaller mass. But in turn, to get it to the higher point more work… Read More
Acceleration is the ration force/mass (Newton's second law) which in free fall is just weight /mass = mg/m = g. Since weight is proportional to mass, the ratio weight/mass is the same whatever the weight of a body
Factors that affect potential energy are mass, height, and acceleration due to gravity. Factors that affect kinetic energy are mass and velocity.
2 carts are pushed with the same amount of force However 1 shopping cart has a greater mass than the other how does the mass of the cart affect their acceleration?
F=ma. Greater mass leads to smaller acceleration given the same force.
Explain how a football and a soccerball can have different accelerations if pushed by the same force?
Force = mass x acceleration, therefore, acceleration = force / mass. Force = mass x acceleration, therefore, acceleration = force / mass. Force = mass x acceleration, therefore, acceleration = force / mass. Force = mass x acceleration, therefore, acceleration = force / mass.
Newton's Second Law: Force = mass x acceleration. Solving for acceleration: acceleration = force / mass. Therefore, if you increase the mass, the same force will produce less acceleration. Newton's Second Law: Force = mass x acceleration. Solving for acceleration: acceleration = force / mass. Therefore, if you increase the mass, the same force will produce less acceleration. Newton's Second Law: Force = mass x acceleration. Solving for acceleration: acceleration = force / mass. Therefore… Read More
Firstly, force is equal to mass of the object into it's acceleration, so acceleration is not a force.Next, the change in velocity of a body over time is called acceleration, so yes, acceleration does affecta body's velocity.
Force = mass x acceleration Mass = Force / acceleration Acceleration = Force / mass
The force of gravity causes objects to accelerate (speed up) when they fall. This is because of newtons law F=MA force equals mass times acceleration, meaning when you put a force such as gravity on a mass it will accelerate the mass
In a vacuum it doesn't A: Since acceleration involves the vector sum of all forces acting on a mass, and resistance to motion (air or fluid resistance, friction, etc) is part of that sum, then shapes that increase or decrease resistance do affect the acceleration of an object as they affect the sum of forces acting on it.
Inertia can be defined as the relunctance of a body to acceleration. Therefore, the greater the inertia of a body, the less it will accelerate under a given force. Inertia is directly related to mass. The greater the mass, the greater the inertia.
Sure. With a constant force, acceleration is inversely proportional to mass. That's why it's so much easier to get a little kid going on a swing than to get a dead car moving by pushing it.
The accelerations are m1a1 = m2a2=f thus a1=f/m1 and a2 = f/m2. The smaller mass has the larger acceleration.