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∙ 12y agoIf the two springs are equal in their dimensions and made from the same material, then the longer spring will require more energy to stretch it, and thus will give back that greater amount of energy when it retracts to its original size.
Wiki User
∙ 12y agoA longer spring will have more elastic potential energy compared to a shorter spring, as the amount of energy stored in a spring is directly proportional to its extension or compression. This means that as the spring is stretched or compressed further, it will have more potential energy stored in it.
Stretching the rubber band creates potential energy within the band. When released, this potential energy is converted into kinetic energy, propelling the rock forward with greater force and speed. The extra stretching increases the amount of potential energy stored, resulting in a faster projectile.
Larger rubber bands tend to fly farther because they store more elastic potential energy that is released when they are stretched and released. The longer the rubber band is, the more energy it can store and transfer to the object being propelled.
The angle of release of a pendulum affects the swing time because it determines the initial potential energy that is converted to kinetic energy during the swing. A larger angle of release results in more potential energy at the start, leading to a longer swing time as the pendulum must swing through a larger arc to reach its highest point. Conversely, a smaller angle of release corresponds to less initial potential energy and a shorter swing time.
You can give a rubber band potential energy by stretching it. When you stretch a rubber band, you are doing work on it, which causes the rubber band to store potential energy in the form of strain energy. This potential energy is released when the rubber band is allowed to return to its original shape.
The wave with a shorter wavelength will transmit more energy, because energy is directly proportional to frequency (which is inversely proportional to wavelength). So, a shorter wavelength corresponds to a higher frequency and thus more energy.
The energy found in food is potential energy. This energy is stored in the chemical bonds of molecules in the food and is released when these bonds are broken down during digestion to produce kinetic energy that our bodies can use for various activities.
Shorter or longer than what ? The wavelength of visible light is shorter than that of radio and heat, and longer than the wavelength of X-ray and gamma radiation. And the wavelength of green light is shorter than red light but longer than blue light.
Stretching the rubber band creates potential energy within the band. When released, this potential energy is converted into kinetic energy, propelling the rock forward with greater force and speed. The extra stretching increases the amount of potential energy stored, resulting in a faster projectile.
Larger rubber bands tend to fly farther because they store more elastic potential energy that is released when they are stretched and released. The longer the rubber band is, the more energy it can store and transfer to the object being propelled.
A shorter wavelength of visible light corresponds to higher energy and a bluer color, while a longer wavelength corresponds to lower energy and a redder color.
The angle of release of a pendulum affects the swing time because it determines the initial potential energy that is converted to kinetic energy during the swing. A larger angle of release results in more potential energy at the start, leading to a longer swing time as the pendulum must swing through a larger arc to reach its highest point. Conversely, a smaller angle of release corresponds to less initial potential energy and a shorter swing time.
You can give a rubber band potential energy by stretching it. When you stretch a rubber band, you are doing work on it, which causes the rubber band to store potential energy in the form of strain energy. This potential energy is released when the rubber band is allowed to return to its original shape.
The wave with a shorter wavelength will transmit more energy, because energy is directly proportional to frequency (which is inversely proportional to wavelength). So, a shorter wavelength corresponds to a higher frequency and thus more energy.
A ball, falling through space, loses potential energy and gains kinetic energy. This is a way to say (in Physics equations) that it goes faster the longer it falls. When the ball strikes a hard surface, the ball is deformed and changes all the kinetic energy to elastic energy. This energy then changes back to kinetic energy as the ball recovers its shape. This is an example of an elastic collision. There is some loss due to air resistance and thermal loss in the conversion from kinetic to elastic and back again, but the ball acts as a good demonstration that energy is conserved in physical processes.
Because if the shorter leg was shorter than the longer leg was long, then the longer leg wouldn't be longer than the shorter leg is short. The short leg would be the longer one rather than the long one being the short one.
Shorter wavelengths correspond to higher energy light, such as ultraviolet and gamma rays, while longer wavelengths correspond to lower energy light, such as radio waves and infrared.
No, it's just a simple walnut. But as it falls, some of the potential energy it had before it fell changes to kinetic energy, and the longer it falls, the more of that conversion takes place.