1.98 x 1030 kg
Any number that is very large, or very small (near zero). For example, the mass of the Sun in kilograms (large), the distance to the M31 galaxy in meters (large), or the mass of the electron in kilograms (small).
Mass of ten 12 kilograms = 10*12 = 120 kilograms
Kilograms.
That depends on where you weigh 142 pounds.-- If you weigh 142 pounds on Earth, then your mass is 64.4 kilograms. (rounded)-- If you weigh 142 pounds on the Moon, then your mass is 389.2 kilograms. (rounded)-- If you weigh 142 pounds on Mars, then your mass is 169 kilograms. (rounded)-- If you weigh 142 pounds on Jupiter, then your mass is 24.4 kilograms. (rounded)...etc.
Yes
The mass of the Sun is about 1.99 x 10^30 kilograms. In terms of size, the Sun has a diameter of about 1.4 million kilometers.
1828 millionThe mass of our Sun is 1.989 x 1030 kilograms
You cannot weigh 45 kilograms because a kilogram is a measure of mass, not of weight. If your mass is 45 kilograms, your weight on the surface of the sun would be 12330 newtons.
The mass of the Sun is about 2 x 10 to the power 30 kilograms.
The mass of the sun is approximately 2x10^30 kilograms. To convert this to tons, you would divide the mass in kilograms by 1,000 (since there are 1,000 kilograms in a ton), which means that the mass of the sun is roughly 2x10^27 tons.
The Wikipedia lists the mass as (1.98855±0.00025)E30 kilograms. The plus-minus, of course, refers to the probable error in the Sun's mass, as currently known. That means this mass is currently known with a probable error of about 0.01%.It is also necessary to realize that the mass of the sun is slowly but continuously decreasing. due mostly to the conversion of mass to energy in fusion (4.29E9 kilograms/second) but also the solar wind (~1E9 kilograms/second). Admittedly this mass loss is so small compared to the probable error in the total mass that it is usually ignored, but still it makes knowledge of "exact mass of the Sun" impossible.
The sun's gravity comes from the mass of the sun itself. Gravity is a fundamental force that arises whenever there is mass or energy in the universe, and it is essential for holding celestial bodies like the sun together and governing their orbits.
1,989,881,989,610,210,000,000,000,000,000 kilograms
Uranus, the seventh planet from the sun, has a mass of about 86 times that of Earth. Its weight would depend on the gravitational force acting upon it, which is determined by its mass and the distance from other celestial bodies.
The mass of the Sun is usually specified in kilograms, which is the international unit for mass. Simply multiply that by 1000, to get the mass in grams. (Since the mass is usually given in scientific notation, just add 3 to the exponent.)
The mass of the Sun is usually specified in kilograms, which is the international unit for mass. Simply multiply that by 1000, to get the mass in grams. (Since the mass is usually given in scientific notation, just add 3 to the exponent.)
The relevant quantity in this case is the mass. The mass of our galaxy's black hole is estimated to be about 4 million times the mass of the Sun. (If you want that in kilograms, look up the mass of the Sun, and multiply that by 4 million.)