0
Just standing there, a skier on the top of the mountain has potential energy. If she uses her poles to push-pull before taking off, she's building up a small amount of kinetic energy. If a skier is then moving down the mountain, his movement downward is kinetic energy which increases as his speed increases. If he or she collides with an immovable object while skiing, kinetic energy abruptly ends. If he or she takes off from the top of the mountain and an avalanche happens to hit at the same time, the kinetic energy of the avalanche engulfs the skier and overpowers the lower kinetic energy of the skier. The skier and avalanche become as if one in the kinetic force of the avalanche--until the skier collides with something or is buried, and thus is separated from the avalanche's kinetic energy which continues until the avalanche stops.
What else can I help you with?
Describe potential energy?
Potential energy is a fundamental concept in physics and plays a crucial role in understanding the behavior of physical systems and the conservation of energy. When the conditions or positions of objects change, potential energy can be converted into other forms of energy, such as kinetic energy or thermal energy, as objects move or undergo changes in their state.
Where does a yo - yo have its greatest potential energy?
at its highest point because potential energy is gravitational energy.
When you stretch out a spring at what point would you have the greatest potential energy?
A spring has maximum potential energy at maximum displacement from equilibrium. This means that the greatest potential energy will occur when a spring is stretched as far as it will stretch or compressed as tightly as it will compress. In an oscillating system, where an object attached to a spring is moving back and forth at a given frequency, the object will oscillate about the equilibrium point, and the potential energy of the system will be greatest (and equal) when the object is farthest from equilibrium on either side.
Changes in energy when a child slides down a slide?
At the top of the slide, the child has a bunch of potential energy. Potential energy becomes converted to kinetic energy as the child accelerates down the slide. At the bottom of the slide, your science teacher will say that all potential energy is converted to kinetic.If your looking to be more technical, some kinetic energy will become heat along the length of the slide via friction. At the end of the slide, the child has to stop right? When the child lands on his feet, or face, the inelastic collision between his feet or face and the sand would produce more heat from kinetic energy. Then he will have neither potential nor kinetic energy, the heat he created would be dissipated into the air, sand, and slide as if everything is back to normal. But he might have some cuts and bruises if he did slide down face first.
What are the two types of potential energy?
There is chemical potential energy, heat potential energy, elastic potential, and gravitational potential energy.
A skier on a hill has potential energy due to?
A skier on a hill has potential energy due to their position above the ground. This energy is a result of gravity pulling the skier downward. As the skier descends the hill, this potential energy is converted into kinetic energy.
A skier who has more blank energy than a skier at the bottom?
A skier at the top has more potential energy
What kind of energy would a skier have if standing at the top of a hill?
A skier at the top of a hill would have potential energy due to their elevated position. This potential energy can be converted into kinetic energy as the skier moves downhill.
What type of energy is A skier at the top of a mountain?
kinetic energy
What is the skier's potential energy at point A?
The skier's potential energy at point A is dependent on the skier's mass, the acceleration due to gravity, and the height of point A relative to a reference point. The potential energy can be calculated using the formula: potential energy = mass x gravity x height.
What energy dose a skier has at the top of a hill and coming down a hill?
At the top of a hill, a skier has potential energy due to their position above the ground. As the skier comes down the hill, this potential energy is converted into kinetic energy as the skier gains speed.
What type of energy does a skier at the top of the mountain has?
A skier at the top of the mountain has potential energy, which is the energy stored in an object due to its position or state. As the skier moves downhill, potential energy is gradually converted into kinetic energy, the energy of motion.
What kind of energy would a skier have at the top of a hill have more than a skier at the bottom of the hill?
A skier at the top of a hill would have more potential energy due to their elevated position compared to a skier at the bottom of the hill. This potential energy can be converted into kinetic energy as the skier descends the hill.
What kind of energy does a skier have at the top of a hill?
A skier at the top of a hill has potential energy, which is the energy stored in an object due to its position or state. This potential energy can be converted into kinetic energy as the skier begins to move down the hill.
What type of energy is a skier poised to take off at the top of a hill?
The skier at the top of the hill has potential energy, which is the energy an object has due to its position or state. As the skier moves downhill, potential energy is converted into kinetic energy, the energy of motion.
When a skier goes up a hill and down a hill what energy is that?
The skier going up the hill gains potential energy due to its height increase, which is stored energy that can be released when the skier goes back down the hill. As the skier goes down the hill, the potential energy is converted into kinetic energy, which is the energy of motion.
What does a skier has a top of a hill and coming down a hill?
A skier at the top of a hill has potential energy due to their height above the ground. As they come down the hill, this potential energy is transformed into kinetic energy, allowing them to slide down the slope thanks to gravity. The skier's speed will increase as they descend due to the conversion of potential energy into kinetic energy.
