Mass is (informally) the "amount of substance". It affects both inertia (resistance to change of movement) and weight. However, the weight also depends on the force of gravity.
Example: An object with a mass of 1 kg., on Earth, will weigh almost 10 Newton.
On the Moon, the same object will still have a mass of 1 kg. (it will require the same force to accelerate), but it will only weigh about 1.6 Newton.
In outer space (in free fall, actually), it will weigh 0 Newton, but it will still have the mass of 1 kg. For example, it can still hurt you if it hits you.
On Earth, mass and weight are proportional, but it is best not to confuse them.
Mass is (informally) the "amount of substance". It affects both inertia (resistance to change of movement) and weight. However, the weight also depends on the force of gravity.
Example: An object with a mass of 1 kg., on Earth, will weigh almost 10 Newton.
On the Moon, the same object will still have a mass of 1 kg. (it will require the same force to accelerate), but it will only weigh about 1.6 Newton.
In outer space (in free fall, actually), it will weigh 0 Newton, but it will still have the mass of 1 kg. For example, it can still hurt you if it hits you.
On Earth, mass and weight are proportional, but it is best not to confuse them.
Mass is (informally) the "amount of substance". It affects both inertia (resistance to change of movement) and weight. However, the weight also depends on the force of gravity.
Example: An object with a mass of 1 kg., on Earth, will weigh almost 10 Newton.
On the Moon, the same object will still have a mass of 1 kg. (it will require the same force to accelerate), but it will only weigh about 1.6 Newton.
In outer space (in free fall, actually), it will weigh 0 Newton, but it will still have the mass of 1 kg. For example, it can still hurt you if it hits you.
On Earth, mass and weight are proportional, but it is best not to confuse them.
Mass is (informally) the "amount of substance". It affects both inertia (resistance to change of movement) and weight. However, the weight also depends on the force of gravity.
Example: An object with a mass of 1 kg., on Earth, will weigh almost 10 Newton.
On the Moon, the same object will still have a mass of 1 kg. (it will require the same force to accelerate), but it will only weigh about 1.6 Newton.
In outer space (in free fall, actually), it will weigh 0 Newton, but it will still have the mass of 1 kg. For example, it can still hurt you if it hits you.
On Earth, mass and weight are proportional, but it is best not to confuse them.
Mass is (informally) the "amount of substance". It affects both inertia (resistance to change of movement) and weight. However, the weight also depends on the force of gravity.
Example: An object with a mass of 1 kg., on Earth, will weigh almost 10 Newton.
On the Moon, the same object will still have a mass of 1 kg. (it will require the same force to accelerate), but it will only weigh about 1.6 Newton.
In outer space (in free fall, actually), it will weigh 0 Newton, but it will still have the mass of 1 kg. For example, it can still hurt you if it hits you.
On Earth, mass and weight are proportional, but it is best not to confuse them.
No. The weight is the mass times the acceleration. W=ma. The weight can be zero if the acceleration is zero, even if the mass is positive. Mass and weight are not the same thing.
weight and mass are the same thing essentially. weight is a measurement of mass. so technically the answer to your question is yes
Yes they are different things. Buoyant force is always upward. Weight is always downward. Also ... -- Weight depends on the object's mass. -- Buoyant force depends on its volume, and on what it's floating in.
Basically by weighing it. Although mass is not the same as weight, if you know the weight and the gravity, you can calculate the mass.Basically by weighing it. Although mass is not the same as weight, if you know the weight and the gravity, you can calculate the mass.Basically by weighing it. Although mass is not the same as weight, if you know the weight and the gravity, you can calculate the mass.Basically by weighing it. Although mass is not the same as weight, if you know the weight and the gravity, you can calculate the mass.
Mass and weight are similar because they are directly proportional to one another. Mass is the measure of matter within an object, and weight is the force with which gravity pulls down on that mass. If the mass is great, the force pulling on it is great.
No. The weight is the mass times the acceleration. W=ma. The weight can be zero if the acceleration is zero, even if the mass is positive. Mass and weight are not the same thing.
Mass.
No it is not.
weight and mass are the same thing essentially. weight is a measurement of mass. so technically the answer to your question is yes
No
No proper data can be used to determine a falsehood, and since mass and weight are NOT the same thing there can be no such data.
Anything that can be weighed in pounds contains mass. But weight and mass are not the same thing.
Yes its the same thing.
Mass and weight are the same thing. *Mass and weight are not the same thing. Mass is the measurement of matter within the object and weight is the force applied to the object from gravity. So, to answer your question a star would have much more mass than weight because there is very little gravity affecting the Sun.
A kilogram is a measure of mass, not of weight. They are not the same thing!
Yes they are different things. Buoyant force is always upward. Weight is always downward. Also ... -- Weight depends on the object's mass. -- Buoyant force depends on its volume, and on what it's floating in.
The relations between mass and weight are that mass shows how much an object contains. This is about the same thing as weight - how much an object contains.