The greater the mass the greater the inertia. Thus if both vehicles were travelling at the same speed the vehicle with the greater mass would have the most inertia and thus be the hardest to stop.
The higher the mass, the greater the velocity of a vehicle. Upon impact, the vehicle may stop however the momentum of the payload continues. As a result the vehicle with less mass will be damaged more.
The mass of an object is directly proportional to its inertia. Inertia is the resistance of an object to changes in its state of motion, and a greater mass means more inertia - meaning it will be harder to accelerate or decelerate the object.
greater
The bowling ball is harder to stop because it has a greater mass, and therefore a greater momentum. But the answer is that the bowling ball has a greater mass.
Greater the gravitational force it exerts on another object.
it can kill people and destroy houses
if there is large mass its harder to get moving and harder to stop than an object that has less mass.
A vehicle's momentum depends on its mass and velocity. The momentum of a vehicle is the product of its mass and its velocity. The larger the mass or velocity of a vehicle, the greater its momentum.
To determine which vehicle has the greater momentum, you need to know the mass of each vehicle. Momentum is defined as momentum = mass x velocity, so the vehicle with the greater mass will have the greater momentum. If the vehicles have the same mass, then they will have the same momentum.
The vehicle with the greater mass will have the greater momentum, as momentum is dependent on both velocity and mass.
Mass corresponds to inertia by affecting an object's resistance to changes in motion. Objects with more mass have greater inertia, meaning they are harder to accelerate or decelerate compared to objects with less mass. This relationship is described by Newton's First Law of Motion.
The amount of mass in a body affects its tendency to resist changes in motion, known as inertia. The greater the mass, the greater the inertia, making it harder to change the body's state of motion. This means that a body with more mass will require more force to accelerate or decelerate compared to a body with less mass.