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Force = Mass x Acceleration Force = 5 x 2 Force = 10N (Newtons)

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The force applied to the mass is ten (10) newtons.

Since force equals mass times acceleration, so, F= ma

=> F = (5 kg)(2 m/s2)

= 10 kg m/s2

or 10 N

force = mass x acceleration = 2 x 5 = 10kg-m/s/s = 10 Newtons

Q: What force of 2.0 kg mass and acceleration of 5.0 MS's on a level surface what is the force applied to the mass?

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13N. if a=0, the sum of all forces is zero so the force of friction is equal and opposite to the dragging force.

20 N is applied to 10 kg mass. 20 N/10 = 2. The acceleration of mass is 2.

F=mam=F/am=20/4.0m=5Kg

The force of gravity (or any force) obey's Newton's Second Law of motion: the force applied to a body is equal to the time derivative of it's momentum. In cases where the mass is constant (practically all of introductory physics and much of graduate-level physics), force is equal to mass times acceleration. (F = ma)

The force acting upon the object as well as the mass of the object. Both will affect the acceleration of the object.

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This can be measured by the acceleration due to gravity at the surface. Earth's surface gravitational acceleration is about 9.8 m/s2

13N. if a=0, the sum of all forces is zero so the force of friction is equal and opposite to the dragging force.

The acceleration of gravity at the surface of the Earth is 9.81 meters per second2 . That means that the downward force on any object at the surface is 9.81 newtons per kilogram of mass.

20 N is applied to 10 kg mass. 20 N/10 = 2. The acceleration of mass is 2.

F=mam=F/am=20/4.0m=5Kg

the weight of a body is the force exerted by gravity to the body and is proportional to the mass of the body. A force applied to a body will give him an acceleration. The relation between the force f applied to the body, its mass m and the acceleration a is given by Newton's second law of motion ; f = ma The acceleration given by gravity to bodies at sea level is referred to as the standard gravity acceleration and has the value of 9.81 m/s2 (rounded to 3 digits). So, if you have a body with mass 0.5 kg, the weight of it at sea level would be, 0.5 kg x 9.81 m/s2 = 4.9 newtons When a body is subject to the standard gravity acceleration a mass of one kilogram (mass kilogram) weights one kilogram (force kilogram). In the International Units System, the unit for mass is the kilogram and the unit of force is the newton. The force kilogram is avoided as to not produce confusion.

The force of gravity (or any force) obey's Newton's Second Law of motion: the force applied to a body is equal to the time derivative of it's momentum. In cases where the mass is constant (practically all of introductory physics and much of graduate-level physics), force is equal to mass times acceleration. (F = ma)

The force acting upon the object as well as the mass of the object. Both will affect the acceleration of the object.

The acceleration of gravity at the 'surface' of Jupiter is 2.639 times its value at the Earth's surface.

acceleration x Mass of trailer = force.

9.81 is the acceleration due to the force of gravity experienced by bodies on or about the surface of the earth (nominally at sea level) the units are meters per second / per second, that is to say a stone dropped from a height will gain 9.81 m/s velocity for every second it falls (is in freefall) however , if you move from the earths surface , this figure will diminish, an example being : if you double your distance from the earths centre you will experience 1/4 of the acceleration (or force) you experienced at the surface

So that all of the motion you observe is the result of the force you applied, and none of it is the result of gravity.