That would depend on the volume (density) of the 10kg object.
98.07 newtons (Force = mass x acceleration)
When a body is moved from sea level to the top of a mountain, its weight changes but its mass remains constant. Weight is the force of gravity acting on an object, so as the body moves to higher altitudes where gravity is weaker, its weight decreases. Mass, on the other hand, is the amount of matter in an object and doesn't change with location.
First off your mass is the same, it will no t change no matter where you are. Your weight however depends on the distance between your center of mass and the center of mass of the earth ( and to a very small extent on the bouyant forces of the atmosphere) So at sea level the force of gravity between you and the earth (your weight) is: F=G x m1x m2/D2 where F is essentially your weight, G is the universal gravitational constant, m is your mass and m2 id the mass of the Earth and D is the distance between you and the center of the Earth. At the top of Everest you are 8.84 km further from the center of the Earth (Earth's radius)so: FTop/Fsealevel = D2sealevel/D2 Top = (6378.1km)2/(6378.1km + 8.84km)2 (about 99.7% of your initial weight)
No. 3 tons is weight, while altitude is distance from sealevel.
Your mass will remain the same regardless of gravity, so if you weigh 240 lbs on Earth, your mass will also be 240 lbs. Weight is the measure of the force of gravity on an object, while mass is the amount of matter in an object.
98.07 newtons (Force = mass x acceleration)
Apply Newton's second law, F mg where F is the weight , m is the mass, and g is the acceleration of gravity at the location where weight is to be determined. At sea level, a 1 kg mass has a weight of 9.8 Newtons F (1kg)(9.8m/s2) 9.8 Newtons The force (weight) exerted on 1 kg at sea level is 2.2 lbs
When a body is moved from sea level to the top of a mountain, its weight changes but its mass remains constant. Weight is the force of gravity acting on an object, so as the body moves to higher altitudes where gravity is weaker, its weight decreases. Mass, on the other hand, is the amount of matter in an object and doesn't change with location.
A kilogram is a unit of mass, not weight. At sea level, a kilogram of mass would still weigh approximately 9.81 Newtons due to the force of gravity.
(10kg)x(9.80665N/kg)=98.0665N at sea level on earth
Your weight(force due to gravity) equals your mass times the acceleration due to gravity(g). g=G*(Mass of Earth)/(r^2) So (force@helens)/(force@sea level)= g(@helens)/g(@sea level)= [(radius of earth)/(radius of the earth+height of helens)]^2 radius of earth = 6378.1 km Altitude of mt helens = 2.55 km Your mass cancels out because it is equal regardless of gravity. So your weight at mt helens is equal to 99.92% of your weight at sea level. Hope that helps
The mass of an object with a weight of 35 newtons can be calculated using the formula: weight = mass x gravity. Assuming gravity is 9.8 m/s^2, the mass would be approximately 3.6 kg.
the mass will always be 50 kg, however, the weight changes depending on different variables. Something that has a weight of 50 kg at sea level will be somewhat lighter in high altitudes, and conversly, something that weighs 50 kg at the peak of Mt Killimanjaro will weigh more at sea level.
About 700N 70kg • 10m/s = 700N
The mass of the air would be 984g at 25C (temperature also has an effect).
The weight of air at sea level is approximately 0.075 pounds per cubic foot. One cubic yard is equal to 27 cubic feet, so the weight of air per cubic yard at sea level would be approximately 2.025 pounds.
None of the above. Mass of an object does not change depending on location. The person's weight would be unmeasurably more at sea level on Earth, a little less on Everest, and much less (1/6th) on the Moon. But their mass is the same at all these locations. There is no other answer.