High
High
Yes. When you stretch a rubber band you are "giving" it mechanical energy, like a rechargeable battery is given electricity. The more you stretch the rubber band the more mechanical energy you are storing in it.
Both a wave with long wavelength and a wave with short wavelength can have a lot of energy, or little energy.Specifically in the case of electromagnetic waves, a short wavelength corresponds to high energy - but this is only the energy PER PHOTON. But note that each of such waves usually consists of a lot of photons.
Depends on the amount of energy in the wave.
Mostly heat, and a little bit of light. A lot like an incandescent light bulb.
WAVES:Ocean waves are an example of a mechanical wavewhere in the energy of the wave is carried by the water. The source, whatever it is, acts in a way to transfer energy into the water. It applies a force on or to the water, and the water "accepts" the energy and it is carried out away from the source by or in the form of a wave. The force displaces the water in some way, and this transfers energy into the water.ENERGY: a thermodynamic quantity equivalent to the capacity of a physical system to do work.
High
Yes, energy is needed for active transport, while energy is not needed to be inputted for passive forms of transport.
"Wave energy" can be a lot of things, you need a more specific question. Energy that travels in "waves" includes a lot of things such as: Radiation, thermal energy, even matter (which has both a wave length and unless frozen, has energy). So... no natural gas is not more available then "wave energy".
A sound wave that has a large amplitude carries a lot of energy because the higher the waves amplitude the louder (more powerful or energetic) the wave will be. apex answer: high amplitude
No.... The Active Transport Requires Energy >> Just Energy But Our Bodies Transport a lot Of Substances Using Active Transport Including Water , Metal Ions, etc .......
The seismic wave's energy get's a-lot smaller
When a wave travels through water, it causes the water molecules to move in a circular motion in the direction of the wave propagation. This circular motion transfers energy from molecule to molecule as the wave passes by, eventually carrying the water molecules along with it. This is how water molecules are transported from the source of the vibration by the wave.
Yes. When you stretch a rubber band you are "giving" it mechanical energy, like a rechargeable battery is given electricity. The more you stretch the rubber band the more mechanical energy you are storing in it.
Recall that mechanical waves are periodic perturbations that move through some kind of medium. The source transfers mechanical energy into the medium to propagate the wave. That said, we can consider a couple of different waves and see how they can be harmful. Sound is a mechanical wave. It can travel through solids and liquids, but we probably think first that it moves through air. So how can that be bad? If you are in the wrong place at the wrong time, a blast of some kind can drive a pressure wave through air and damage your hearing. Heck, listening to your headphones at high volume can do this to a lesser degree. This is a direct effect of a dangerous level of mechanical energy. How about a couple of examples of harm by what might be termed indirect effect? Let's get to them. A tsunami is a mechanical wave that moves across the sea. The wave itself may not be fatal, but drowning is a real possibility. We have fresh examples of the human toll taken by these mechanical waves. Enough said about that, yes? Yes. We know that earthquakes generate mechanical energy, and they can generate a lot of it. Again, the moving ground might not injure anyone, but falling structures can. History is replete with examples of the damage done by quakes, and injuries and fatalities mount up in any assessment.
Chemical energy (stored in the bonds of the molecules). When it burns, a lot of that energy becomes heat and a lot of that heat gets converted to internal energy as the hot combusted gas products reach high pressure with increasing temperature. The pressure pushes the pistons (kinetic energy) which translates to mechanical energy, which moves the car - which has kinetic energy as it moves.
Both a wave with long wavelength and a wave with short wavelength can have a lot of energy, or little energy.Specifically in the case of electromagnetic waves, a short wavelength corresponds to high energy - but this is only the energy PER PHOTON. But note that each of such waves usually consists of a lot of photons.
Sensible Energy, Latent Energy, chemical energy, nuclear energy, mechanical energy, internal energy, and a LOT more. Well, these arent the BEST types of energy but.. yeah...