drag each label to the correct location on the image. each label can be used more than once, but not all…

drag each label to the correct location on the image. each label can be used more than once, but not all labels will be used. emma is an adventurer. she hikes up a mountain to go bungee jumping. complete the energy - chain diagram representing the energy transformations that emma and the rope encounter. elastic potential energy chemical potential energy electric potential energy motion energy gravitational potential energy emma standing on top of mountain emma jumping down from mountain top tension in rope at emmas lowest position emma bouncing back reset next

drag each label to the correct location on the image. each label can be used more than once, but not all labels will be used. emma is an adventurer. she hikes up a mountain to go bungee jumping. complete the energy - chain diagram representing the energy transformations that emma and the rope encounter. elastic potential energy chemical potential energy electric potential energy motion energy gravitational potential energy emma standing on top of mountain emma jumping down from mountain top tension in rope at emmas lowest position emma bouncing back reset next

Answer

Explanation:

Step1: Identify energy at top - most position

When Emma is standing on top of the mountain, she has gravitational potential energy due to her height above the ground. The formula for gravitational potential energy is $U = mgh$ (where $m$ is mass, $g$ is acceleration due to gravity and $h$ is height). So the first box is gravitational potential energy.

Step2: Identify energy during descent

As Emma jumps down from the mountain top, her height decreases and her speed increases. Her gravitational potential energy is converted into motion energy (kinetic energy). The formula for kinetic energy is $K=\frac{1}{2}mv^{2}$ (where $v$ is velocity). So the second box is motion energy.

Step3: Identify energy at lowest position

At Emma's lowest position, the bungee - rope is stretched to its maximum. The energy is stored as elastic potential energy in the stretched rope. The formula for elastic potential energy is $U_{s}=\frac{1}{2}kx^{2}$ (where $k$ is the spring constant and $x$ is the displacement from the equilibrium position). So the third box is elastic potential energy.

Step4: Identify energy during bouncing back

When Emma bounces back, the elastic potential energy stored in the rope is converted back into motion energy as she moves upwards. So the fourth box is motion energy.

Answer:

Gravitational potential energy; Motion energy; Elastic potential energy; Motion energy