Inertia is related to speed and mass; a train is both faster and more massive than a car.
A train would have more inertia than a car because inertia is determined by an object's mass, and trains typically have much greater mass than cars. Inertia is the tendency of an object to resist changes in its state of motion, so an object with more mass (like a train) will have more inertia compared to an object with less mass (like a car).
A train has more inertia than a car because inertia depends on mass, and trains are typically much heavier than cars. Even if both the train and car were moving at the same velocity, the train's higher mass means that it requires more force to change its speed or direction, giving it greater inertia.
A train has greater inertia than a car. This is because the train's mass is larger, so it requires more force to accelerate or decelerate compared to a car due to its greater resistance to changes in motion.
It is easier to stop a car than a train because cars have smaller mass and less momentum than trains. Cars can also use friction from their brakes to slow down more quickly than trains, which rely on more complex braking systems due to their size and weight. Additionally, trains travel on tracks, which limits their ability to maneuver or stop suddenly.
1500kg. "Inertia" is a measurement of resistance of an object to a change of it's motion. Oversimplified, a train has more inertia than a car. The more mass, the more inertia, it applies to acceleration and deceleration equally. Galileo demonstrated inertia before Newton's "First Law of Motion" Here is the interesting part: It does not require force to keep an object in motion. Rather, it is a force that brings an object to rest. That being friction. Inertia must not be confused with momentum, they are two different things in physics.
A train would have more inertia than a car because inertia is determined by an object's mass, and trains typically have much greater mass than cars. Inertia is the tendency of an object to resist changes in its state of motion, so an object with more mass (like a train) will have more inertia compared to an object with less mass (like a car).
A train has more inertia than a car because inertia depends on mass, and trains are typically much heavier than cars. Even if both the train and car were moving at the same velocity, the train's higher mass means that it requires more force to change its speed or direction, giving it greater inertia.
A train has greater inertia than a car. This is because the train's mass is larger, so it requires more force to accelerate or decelerate compared to a car due to its greater resistance to changes in motion.
It takes less force to stop a train than to stop a car.
Among a bowling ball, a planet, a car, and a train, the planet has the greatest inertia. Inertia depends on an object's mass, and planets have significantly more mass than the other items listed, meaning they resist changes to their motion more than the others do. While a bowling ball is heavy, it pales in comparison to the mass of a planet.
The train is heavier than the car is and the train has more things in the back. The train is heavier than the car is and the train has more things in the back.
It is easier to stop a car than a train because cars have smaller mass and less momentum than trains. Cars can also use friction from their brakes to slow down more quickly than trains, which rely on more complex braking systems due to their size and weight. Additionally, trains travel on tracks, which limits their ability to maneuver or stop suddenly.
1500kg. "Inertia" is a measurement of resistance of an object to a change of it's motion. Oversimplified, a train has more inertia than a car. The more mass, the more inertia, it applies to acceleration and deceleration equally. Galileo demonstrated inertia before Newton's "First Law of Motion" Here is the interesting part: It does not require force to keep an object in motion. Rather, it is a force that brings an object to rest. That being friction. Inertia must not be confused with momentum, they are two different things in physics.
The car with a mass of 1500 kg has more inertia than the car with a mass of 900 kg. Inertia is directly proportional to mass, so the car with greater mass will have greater inertia.
I am almost certain they would have the same inertia.
A large truck typically has more inertia than a small car because inertia is directly proportional to an object's mass. The greater mass of the truck means it will resist changes in its state of motion more than the smaller car.
A car is much, much lighter than a train, and requires less force both to go into motion and to come to a stop. Even though a train has many more sets of brakes and a much more powerful motor, the ratio of engine power to weight and braking power to weight is much greater in a car, allowing the car to go into motion and come to a stop with much less effort than what is required to do the same with a train.