How does energy transmission work in waves?

In summary, the conversation discusses the confusion surrounding energy transmission in waves, particularly in regards to how kinetic and potential energies vary and remain constant as the wave travels. The experts clarify that the total energy density remains constant, but it may vary at different points within the wave. They also explain that this principle applies to both electromagnetic and string waves.
  • #1
Owen-
40
0
After looking at my notes and http://cnx.org/content/m16027/latest/" I have become utterly confused about Energy transmission in Waves.

Since the expression of elastic potential energy is same as that of kinetic energy

What? In a traveling wave KE=PE?

If so, when a particle is at its max displacement, KE=PE=0 and so KE+PE=0
and yet then a particle is as its mean position KE=PE= constant >0

How is this possible? KE+PE is total energy, shouldn't this be constant? I.e. when KE increases PE decreases but total energy remains the same?

Apologies if this is a stupid question :P
Owen.
 
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  • #2
Depends on what kind of wave you're talking about. The kinetic energy plus the potential energy at a point is the energy density at that point. Energy conservation says that this energy density will remain constant as it travels along with the wave. It does not say that the energy density is the same at all points within the wave. For example for an electromagnetic wave there will be places where E = B = 0, and here the energy density is zero. At other places E and B are both max. That's why we take care to speak about the average energy density.
 
  • #3
Ah ok thanks :) Just let me confirm - in a traveling wave the energy traveling in the y direction varies, but the energy transmitted along the x-axis remains constant? :s
 
  • #4
It sounds like you are talking about waves on a string. In that case, potential energy does not always equal kinetic energy. When a part of the string is at its maximum displacement, it is momentarily at rest and therefore has no kinetic energy. All of its energy is potential. When that part of the string reaches the midpoint of its swing, it is at its maximum speed so all of its potential energy has been converted to kinetic energy. The total energy is constant so PE and KE trade off back and forth as the wave oscillates. Think of it like a pendulum.
 
  • #5
Except it is not like a pendulum. Waves on a string behave the same way as described above for electromagnetic waves. When a part of the string is at its maximum displacement, it has no kinetic energy and no potential energy. When a part of the string reaches the midpoint of its swing, it has both maximum kinetic energy and maximum potential energy. The energy travels along the string. It is maximum at some places and zero at others, but does not remain constant at a particular point.
 

Related to How does energy transmission work in waves?

1. What are waves and how do they transmit energy?

Waves are a form of energy transmission that involves oscillations or vibrations in a medium. This can include mechanical waves, such as sound waves, or electromagnetic waves, such as light waves. Waves transmit energy by causing particles in the medium to vibrate and transfer energy to neighboring particles.

2. How does the energy of a wave change as it travels?

The energy of a wave is always conserved, meaning it does not change as it travels. However, the amplitude or height of the wave may decrease as it spreads out over a larger area, leading to a decrease in energy density. Additionally, some energy may be lost through interactions with the medium or other objects.

3. What factors affect the speed of wave transmission?

The speed of wave transmission depends on the properties of the medium it is traveling through, such as density, elasticity, and temperature. In general, waves travel faster through stiffer and less dense materials, and slower through softer and denser materials.

4. Can waves be used to transfer energy over long distances?

Yes, waves can be used to transfer energy over long distances. Electromagnetic waves, such as radio waves, are commonly used for long-distance energy transmission, particularly for communication purposes. Sound waves can also be used to transfer energy over long distances, such as in the case of whale songs traveling through the ocean.

5. Are there any risks associated with energy transmission by waves?

There can be risks associated with certain types of energy transmission by waves, such as exposure to harmful radiation from electromagnetic waves. However, proper regulation and safety measures can help mitigate these risks. Additionally, there may be environmental impacts from certain types of energy transmission, such as noise pollution from sound waves or disruption of ecosystems from electromagnetic waves.

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