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Assuming the larger mass is moving at the same speed as the original mass, the kinetic energy will double.
The sum of the potential and kinetic energy of large-scale objects in a system is the Hamiltonian.
The sum of the potential and kinetic energy of large-scale objects in a system is the Hamiltonian.
Maybe and maybe not. It depends on the speed of the two objects. A small object moving very fast might have more kinetic energy than a large object moving slowly.
A moving fan is an example of kinetic energy, the energy of objects in motion. An example of potential energy would be a large rock at the edge of a cliff. If the rock falls off the cliff, its potenital energy (energy by virtue of its location), is converted to kinetic energy, energy of its motion, as it falls.
Assuming the larger mass is moving at the same speed as the original mass, the kinetic energy will double.
The sum of the potential and kinetic energy of large-scale objects in a system is the Hamiltonian.
The sum of the potential and kinetic energy of large-scale objects in a system is the Hamiltonian.
Maybe and maybe not. It depends on the speed of the two objects. A small object moving very fast might have more kinetic energy than a large object moving slowly.
The mass of the most objects is too small to cause a force large enough to notice. This is why you don't see the objects moving toward each other.
Yes.
A moving fan is an example of kinetic energy, the energy of objects in motion. An example of potential energy would be a large rock at the edge of a cliff. If the rock falls off the cliff, its potenital energy (energy by virtue of its location), is converted to kinetic energy, energy of its motion, as it falls.
Planets do not require energy to grow. Large spacial objects crash into them and they collect. PLANTS on the other hand, they get energy from the sun.
Fast-moving predators need a large amount of food because they burn more energy when thy are hunting. They need more food, to supply the greater amount of energy they use.
The energy is produced by colliding charged particles.
The energy is produced by colliding charged particles.
From the impact of fast moving objects with a surface. The kinetic energy of the impactor excavates a crater with an inverted, raised rim and forms an ejector plume leaving a crater and, if the impactor is sufficiently large or fast, a central mountain peak.