Small force on small mass :When we exhale the air the force of exhaled air is less. Tiny particles of less masses are present in the nearer air and they start moving with large velocity. On Large mass : it's well explained in pascal's law. From that we can apply small force on larger mass .
Gravitationally, the same force does not affect a small mass and a large mass.
The small mass is acted upon by a smaller gravitational force, and the large mass
is acted upon by a larger gravitational force. The result is that the small mass and
the large mass fall with the same acceleration, and meet the ground with the same
speed. During the fall, onlookers typically nudge each other and remark to each other:
"My word! The large mass weighs more than the small mass!" They are correct in their
impression, and the scientific reason behind their perspicacious observation is the fact
that the gravitational force acting on the large mass is greater than the gravitational
force acting on the small mass.
Momentum is produced if the object is in motion.
Nothing on the list you provided with the question describes that.
When you apply a force to a mass you produce acceleration. "Tiny" and "large" are not well defined here, but the basic equation is F = ma, so if the forces are proportional to the masses in each case (for example, a 0.1 N force applied to a 0.1 g object and a 1000 N force applied to a 1000 g object) then you will produce the same acceleration for both objects.
Torque is the product of (force) x (distance from the center of rotation).So with a distance from the center that's large enough or small enough,any force can produce as much or as little torque as you want.
It will stay at rest.
The large mass can have proportionately more force applied to it than to the smaller mass.
It sounds as if you're looking for an equation that will tell you that number. Thereason you haven't found it yet is that there's no such equation.The effect that force has on a moving object is to 'accelerate' it ... change thedirection it's moving, slow it down, speed it up, etc. ... only depending on thedirection of the force compared to the direction of the motion.If you want to stop a moving object, you apply a force to it opposite to the directionit's moving. It makes no difference how large or small the force is. As soon as it startsacting on the object, the object begins to slow down, and you only have to wait for itto stop. Of course, the larger the force is, the sooner the object stops. But in principle,you can stop an asteroid with the force of a feather, if you're willing to wait long enough.There's no such thing as the amount of force 'needed' to stop the object.
When you apply a force to a mass you produce acceleration. "Tiny" and "large" are not well defined here, but the basic equation is F = ma, so if the forces are proportional to the masses in each case (for example, a 0.1 N force applied to a 0.1 g object and a 1000 N force applied to a 1000 g object) then you will produce the same acceleration for both objects.
It applies a small amount of force to produce a large amount of force.
No this causes an unbalanced force or a balanced forceNO chizz you rape the poor person!
There is no specific force required to accelerate an object to a predetermined speed. A smaller force will produce a smaller acceleration, so it will take longer to reach the desired speed. A larger force will produce a larger acceleration, so the desired speed will be reached sooner. But either the large or the small force, or any other force, will produce an acceleration, and cause the object to reach the specified speed sooner or later.
Torque is the product of (force) x (distance from the center of rotation).So with a distance from the center that's large enough or small enough,any force can produce as much or as little torque as you want.
The large body will have a strong force of opposing friction, related to its large weight. The force of friction between two materials is equal to the normal (perpendicular) force between them, times a factor (the so-called coefficient of friction), which depends on the materials, but is typically less than one.
It will stay at rest.
It will stay at rest.
There is no such object. Any object on which a force is applied will accelerate (i.e., its velocity will change over time). If the object has a very large mass, the effect will be hardly noticeable for any given force.
The actual force may be the same, but a screwdriver with a large HANDLE can be more effective in applying that force. You can grip it and apply force easier.
The effect of a force depends on the mass of the object to which it's being applied. Small force on a low-mass object produces the same identical motion as large force on a large-mass object. So ... in addition to other mathematical and physical problems with the connection between force and escape ... it's impossible to name one force that always has the same effect on any object large or small.But escape velocity is truly a speed at which any object, large or small size, large or small mass, can enter earth orbit. There is another speed at which any object can escape earth and enter solar orbit, and another speed at which any object can escape the sun and leave the solar system. Specifying the speed eliminates the necessity of specifying the characteristics of the object you're talking about.
The large mass can have proportionately more force applied to it than to the smaller mass.