The Rock Cycle and the Law of Conservation of Mass are related because the processes involved in the rock cycle (such as weathering, erosion, and deposition) do not create or destroy matter, they only transform it from one form to another. This is consistent with the Law of Conservation of Mass, which states that matter is neither created nor destroyed in a chemical reaction.
The metal will rust over time but the mass of the container as a whole. The law of conservation of mass is not violated.
When rocks change form in the rock cycle, you see an example of the conservation of matter, where the total amount of matter in the system remains constant. This means that rocks may transform through processes like erosion, deposition, heat, and pressure, but the total mass of the rocks remains the same throughout the cycle.
When a metamorphic rock melts, it transforms into magma rather than lava, as lava refers specifically to magma that has erupted onto the Earth's surface. During this melting process, the minerals in the rock may undergo changes, but the overall mass is conserved according to the law of conservation of mass. Once the magma reaches the surface and erupts, it cools and solidifies into igneous rock, completing the rock cycle. Thus, while the form of the material changes, the total mass remains constant throughout these processes.
Law of Conservation of mass(atomic mass). As mass can be considered relative to energy, therefore Law of Conservation is also correct but Law of conservation of mass is is much more accurate because here mass is a much more accurate term that is required here. Here, since, we are balancing molecules, then we require atomic or molecular mass.
The law that states mass cannot be created or destroyed in chemical or physical changes is the Law of Conservation of Mass, also known as the Principle of Mass Conservation. This law implies that in a closed system, the total mass remains constant before and after any chemical or physical process, even if the substances undergo a change in form or state.
Conservation of mass.
When rocks change form in the rock cycle, we see an example of the conservation of mass. This principle states that the total mass of the rock remains constant throughout the cycle, even as it undergoes various processes such as weathering, erosion, and sedimentation.
The laws of conservation of mass applies to the rock cycle because the rocks in the rock cycle relate to matter. The law of conservation of mass says mass cannot be created or deystroyed. The rock cycle shows how differrent liquids turn to gases and solids turn to liquids, etc. When each of them change to different forms their mass isn't more or less, because the matter in which made up the starting product doesn't gain or loose, it stays exactly the same.
The principle behind Earth's cycles such as the rock cycle, carbon cycle, and water cycle is the concept of conservation of matter. This principle states that matter is neither created nor destroyed but is instead transformed and recycled through various processes on Earth. This allows for the continuous cycling of elements and molecules through different spheres of the Earth.
The metal will rust over time but the mass of the container as a whole. The law of conservation of mass is not violated.
contrast the water cycle and law of conservations answer
This demonstrates the conservation of mass, as the total mass of the rock remains the same even though it has been weathered into smaller pieces.
This scenario demonstrates the conservation of mass. Weathering breaks down the rock into smaller pieces, but the total mass of the smaller pieces remains equal to the original rock.
It isn't closely related. Newton's Third Law is more closely related to conservation of MOMENTUM.
When rocks change form in the rock cycle, you see an example of the conservation of matter, where the total amount of matter in the system remains constant. This means that rocks may transform through processes like erosion, deposition, heat, and pressure, but the total mass of the rocks remains the same throughout the cycle.
The copper cycle demonstrates the principle of conservation of matter by showing that the total mass of copper remains constant throughout the various chemical reactions. At the end of the cycle, the total mass of copper atoms in the system is the same as it was at the beginning, even though the copper goes through different chemical transformations. This supports the idea that matter cannot be created or destroyed in a closed system.
The law of conservation of mass states that mass is neither created nor destroyed in a chemical reaction. Stoichiometry is the calculation of reactants and products in chemical reactions based on the law of conservation of mass. It helps determine the quantitative relationships between substances involved in a chemical reaction.