Wiki User
∙ 16y agoDensity does not change regardless of where the object is. It is a constant.
Wiki User
∙ 16y agoLook up the density of steel. It should be no different in a spaceship than on Earth.
The density is not affected by gravity. it is a measure of a substances mass to volumn. Therefor the density of a steel hammer on a spaceship is the same as one on earth (approx 7850 kg/m^3)
The density of the hammer is the same no matter where it is. Density = Mass / volume. Neither Mass nor volume is dependent on gravity there for Density is also independent of gravity.
Because mass is not the same as weight. Weight is mass times gravity so your weight will change if you are on the earth or moon but your mass will stay the same.
Density = mass / volume since earth is nearly spherical, Volume = (4/3)pi x r3 find volume, then divide this into the mass.
Look up the density of steel. It should be no different in a spaceship than on Earth.
The density is not affected by gravity. it is a measure of a substances mass to volumn. Therefor the density of a steel hammer on a spaceship is the same as one on earth (approx 7850 kg/m^3)
The density of the hammer is the same no matter where it is. Density = Mass / volume. Neither Mass nor volume is dependent on gravity there for Density is also independent of gravity.
Density does not change because density is measured by Mass/Volume. So whether you're on earth, on the moon or floating in space, your density remains the same. Pressure, on the other hand, changes because it is defined as force per unit area (Force/Area). Your weight is the force here. As you approach the earth, the value of g increases, and so does the value of force.
Density stratification in Earth's interior played a key role in planetary differentiation, resulting in the formation of distinct layers such as the crust, mantle, and core. This process greatly influenced the evolution of Earth's magnetic field, plate tectonics, and overall geodynamic processes.
gets heavier
The deeper you get into the earth, the more weight you have above you. This results in pressure that increases the density of the material below.
If a solid object is taken from Earth into space, it would experience several changes. It would become weightless due to the absence of gravity, and its temperature may fluctuate significantly depending on its exposure to the sun. Additionally, without Earth's atmosphere to protect it, the object may be subjected to higher levels of radiation in space.
The density on Earth is higher than in a spaceship, as the spaceship is typically designed to be lightweight. On Earth, the atmosphere and gravitational force contribute to a denser environment, whereas a spaceship is constructed to be less dense for efficient travel in space.
Air density is higher near the surface of the Earth. As you climb away from the surface, the pressure decreases.
The Moon's average density is about the same as the density of the Earth's mantle.
The zone where density increases the most for any unit change in depth is the uppermost layer of the Earth's mantle called the transition zone. This zone extends from about 400 to 670 kilometers below the Earth's surface and marks a significant increase in density due to changes in mineral composition and pressure.