yes. newtons 2nd law says that when force increases then so dose acceleration. and when mass increases acceleration decreases.
== F=m*a Force = mass * speed a = F/m For the same Force F the speed is big for small mass the speed is small for big mass == The more mass something has, the more force is required to accelerate it to a given speed. The less mass something has, the less the force required to accelerate it to a given speed. Simple and easy. For a given amount of force, the less the mass it is applied to, the higher the speed that will result. The more the mass to which it is applied, the lower the speed that will result. It's just that simple.
Mass and force are directly proportional, therefore: more mass = greater force (Equation: F = ma). Mass and speed are inversely proportional, so: more mass = lesser speed (Equation: p = mv).
Inertia is related to speed and mass; a train is both faster and more massive than a car.
Some objects have more mass, some have less.Some objects have more mass, some have less.Some objects have more mass, some have less.Some objects have more mass, some have less.
Yes, weight, or more precisely mass*, does have an impact on force. The impact is something like this: an object moving at a constant speed will have more force than an object traveling at the same speed with less mass.So, more mass equals proportionately more force.*Mass is a direct measurement of the amount of stuff in an object. Weight is the measurement of the apparent force of gravity on an object.
Mass doesn't affect speed directly; it only affects momentum and acceleration directly. The equations are Force = mass x acceleration. The heavier it is, the more force you have to exert to accelerate something. The other one is momentum = mass x velocity (or speed). The more mass something has, the lower the momentum. But the point I'm trying to make here is that it affects speed in the end -- the more mass something has, the less the speed -- but that's IN THE END. It doesn't really affect it directly, but indirectly. Sorry for not being able to make that more clear.
== F=m*a Force = mass * speed a = F/m For the same Force F the speed is big for small mass the speed is small for big mass == The more mass something has, the more force is required to accelerate it to a given speed. The less mass something has, the less the force required to accelerate it to a given speed. Simple and easy. For a given amount of force, the less the mass it is applied to, the higher the speed that will result. The more the mass to which it is applied, the lower the speed that will result. It's just that simple.
it can be more or less buoyant be having more or less mass.i.e. lead will sink in water because the mass is higher and wood will float because it is lighter. the more mass the less buoyant, less mass means more buoyant.
Mass and force are directly proportional, therefore: more mass = greater force (Equation: F = ma). Mass and speed are inversely proportional, so: more mass = lesser speed (Equation: p = mv).
The electron, because it has much less mass than the proton and momentum is the product of mass and speed.
Mass is the same no matter where you are. Weight is less, but mass is the same.
Inertia is related to speed and mass; a train is both faster and more massive than a car.
Some objects have more mass, some have less.Some objects have more mass, some have less.Some objects have more mass, some have less.Some objects have more mass, some have less.
No , but less mass and less density .
no more, inertia is proportional to mass
Yes the weight does affect the speed of a skateboard.....if your 90 pounds and your ridding with a 105 pound person the 90 pound person will go faster!!!!
As an object accelerates toward the speed of light it's mass (and weight) increases, at the speed of light (c) the objects mass would be infinite, making it impossible for any object to accelerate to light speed. So, "no" an object does not weigh less by moving faster in a vacuum, the faster it goes the more it weighs and the slower time goes. The change in mass and time occurs because near light speed the variable "c" is more fixed and the remaining variables (time and mass) must change to maintain balance.