Weight is directly proportional to mass and the acceleration of gravity: W = mg. On Earth, g = 32.2 ft/s2 or 9.8 m/s2. On the moon, it's much less; on Jupiter, it's much more. In space, it's zero.
Only very slightly - according to the Special Theory of Relativity, an increase in energy means a corresponding increase in mass. Since at a higher position an object has more potential energy, it follows that it has slightly more mass.
Only very slightly - according to the Special Theory of Relativity, an increase in energy means a corresponding increase in mass. Since at a higher position an object has more potential energy, it follows that it has slightly more mass.
Only very slightly - according to the Special Theory of Relativity, an increase in energy means a corresponding increase in mass. Since at a higher position an object has more potential energy, it follows that it has slightly more mass.
Only very slightly - according to the Special Theory of Relativity, an increase in energy means a corresponding increase in mass. Since at a higher position an object has more potential energy, it follows that it has slightly more mass.
Only very slightly - according to the Special Theory of Relativity, an increase in energy means a corresponding increase in mass. Since at a higher position an object has more potential energy, it follows that it has slightly more mass.
Weight. Because mass is a measure of the amount of matter in an object; weight is not.
Mass may change in time but not in location (on this planet) The IPK (international prototype Kilogram) lost mass even though it is protected from all elements and human contact
No, the mass of an object is the same, regardless of gravitational pull or location.
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Independent
No
no
Acceleration is a net force that is inversely dependent on mass, therefore if an object mass increases ,acceleration decreases
No, look at a the the size of a beachball and the size of a Bowling ball. Answer2: Yes. The weight of an object is dependent on mass. Weight = mass times gravity acceleration g, W = mg.
Independent
no
No
Mass.
no
Acceleration is a net force that is inversely dependent on mass, therefore if an object's mass decreases, acceleration increases.
The location like moon will affect its weight but not the mass
Acceleration is a net force that is inversely dependent on mass, therefore if an object mass increases ,acceleration decreases
No, look at a the the size of a beachball and the size of a Bowling ball. Answer2: Yes. The weight of an object is dependent on mass. Weight = mass times gravity acceleration g, W = mg.
yes the less mass it has the more acceleration.
Acceleration is a net force that is inversely dependent on mass, therefore if an object mass increases ,acceleration decreases
The mass of an object is the object's mass. It makes no difference where the object is, what the temperature is, whether it's night or day, on Earth or the far side of the moon, in the northern or western hemisphere, at the bottom of the deepest ocean or on top of the highest mountain, asleep or awake. Whatever mass it had yesterday, wherever it was, is the same mass it has today, wherever it is. Have I made myself clear ?