Mass is an intrinsic property of matter, but weight is mass times the acceleration of gravity. So, mass does not change; you have the same mass on the moon as you have on earth, but gravitational pull is much stronger on earth than the moon, so you weigh more on earth.
Mass of crust = 19.1 zetagrams (1.913x1022kg).
It is not possible to give an exact answer to this question as the Earth's crust varies in thickness and in density. However it is possible to make an estimate, although this will contain errors due to the simplifying assumptions it will be necessary to make.
Earth's crust varies in thickness from as little as 2km thick to over 70 km thick with an average value of approximately 35 km for the continental crust and 4.5 km for the oceanic crust.
Approximately 70 % of Earth's surface is covered in ocean and so it is assumed that this is the proportion of the crust formed of the denser, but thinner oceanic crustal rocks whereas the remaining 30 % is assumed to be composed of the thicker but less dense continental crustal rocks.
Density: It is assumed that the continental crust has an average density of 2700 kg/m3 and the oceanic crust a density of 3000 kg/m3.
Diameter of Earth = 6360 km.
As such, based on the above assumptions an estimation of the mass of the crust can be made by:
Calculating the volume of crustal material:
Volume of Earth = 4/3 x Pi x (6360 x 1000)3
Volume of Earth = 1.07761x1021 m3
Volume of Earth excluding oceanic crust:
Volume = 4/3 x Pi x (6356 x 1000)3
Volume of Earth excluding oceanic crust = 1.07532x1021 m3
Volume of Earth excluding continental crust:
Volume = 4/3 x Pi x (6325 x 1000)3
Volume of Earth excluding continental crust = 1.05991x1021 m3
As such the average volume of continental crust equals:
Volume = (1.07761x1021 - 1.05991x1021)
Volume = 1.76929x1019 m3
As such the average volume of oceanic crust equals:
Volume = (1.07761x1021 - 1.07532x1021)
Volume = 2.28575x1018 m3
Mass = Density x Volume:
Mass of oceanic crust = 2.28575x1018 x 3000 x 0.7
Mass of oceanic crust = 4.8x1021 Kg
Mass of continental crust = 1.76929x1019 x 2700 x 0.3
Mass of continental crust = 1.433x1022Kg
Sum of masses of continental and oceanic crust :
Mass of crust = 1.913x1022 kg.
Earth's mass is 5,882 sextillion metric tons.
5.97 x 1024 kilograms.
5.9 x 10^27 g
On Earth, 1.09 grams of mass weighs 0.0384 ounce. (rounded)
One pound is the weight of 453.59 grams of mass on Earth.
If the mass is 5 grams on Mars.Then the mass is also 5 grams on Earth (by definition).Now, they've specified that the acceleration due to gravity is 9.8 m/s/s, which is "normal".So, the weight would also be 5 grams, or you can convert to whatever your favorite unit is, pounds, ounces, etc.
On Earth, 1 pound is the weight of 453.593grams of mass. (rounded)
On Earth, 41 grams of mass weighs 1.45 ounces.It has different weight in other places.
The mass is 64.44 grams. But the difference between mass and weight is that mass is weight is how heavy it is on the planet you weigh it on and mass it the weight it is on Earth, whether is is on Earth, or not.
3100
6.705909598079999e+27 grams
Your mass, in grams, on Pluto, will be the same as your mass on earth or anywhere else. Your weight cannot be measured in grams.
Go to the Wikipedia, and look up the mass in kilograms. Then multiply that by 1000 to convert to grams. (Since you will find the number in scientific notation, this means adding 3 to the exponent.)
On Earth, 453.593 grams of mass (rounded) weigh one pound.
On Earth, 20 grams of mass weighs 0.0441 pound. (rounded)
One pound is the weight of 453.59 grams of mass on Earth.
On Earth, 1.09 grams of mass weighs 0.0384 ounce. (rounded)
mother earth
If the mass is 5 grams on Mars.Then the mass is also 5 grams on Earth (by definition).Now, they've specified that the acceleration due to gravity is 9.8 m/s/s, which is "normal".So, the weight would also be 5 grams, or you can convert to whatever your favorite unit is, pounds, ounces, etc.
On Earth only, 12 grams of mass weighs 0.0265pound = 0.423 ounce.