It is important to understand that the energy of a substance is directly proportional to its wavelength. This means that the energy of the sun’s rays can be converted into a series of photons that are reflected around the earth, returning to the source. We can use the same reasoning to understand that the energy of a substance may be converted into other substances through the intermediary of other substances. We can, for example, convert the energy of the sun into photons that go through the earth to reach us.
A lot of people talk about how the energy of a substance is directly proportional to its wavelength. There may be other factors that also cause this effect, but this has been the most common explanation for the phenomenon in the popular books and magazines we have on the subject. There is a more basic explanation that’s easier to understand.
If you take our two words “energy” and “wave” and apply the concept of a wavelength to them, you will see that energy is not really a thing in the physical world, it’s a concept. It’s like you have to work hard to make a photon, and when you do you have to do it with enough energy that it has enough energy to become an electron.
So when you say energy, you’re not just talking about the physical process, but also the concept of energy itself. When you see a photon, you don’t actually see a photon, you see a wavelength. That wavelength is the energy of the photon in the physical world. To find that wavelength you have to work hard to make the photon, which means you have to move that wavelength a tiny bit closer and a tiny bit farther.
We are made of energy, so we are made of a certain type of energy in the physical world. This is the energy of the photon. When we make a photon, we create that energy and we move the wavelength that has that energy a tiny bit closer and a tiny bit farther. The wavelength that has that energy a tiny bit closer and a tiny bit farther is closer to the electron than a photon is. The electron has a much larger wavelength and thus a much smaller energy than a photon.
The electrons are the building blocks of atoms. The photons are our energy, and they carry energy around in waves which have a certain wavelength. The wavelengths of photons are much smaller than the wavelengths of electrons. As a result, the photons have much more energy to work with than electrons, so they are able to carry much more energy than a photon. If you take away the energy of a photon, the electron loses energy, and the electron loses speed.
So the photon is the building block of the atom, but the electron has less energy and a smaller wavelength than the photon. This means that the photon has more energy than an electron and thus carries more energy than a photon.
The energy in a photon, however, is not the energy of the electron. The energy of a photon is given by the quantity of photons that pass in a given time interval. So an electron has a certain energy that the photon carries, but the energy of a photon is not given by the photon’s quantity of photons. The energy of a photon is given by the speed of the photon, which is not the speed of the electron.
The energy in a photon, though, is not the quantity of photons that passed in a given time interval. The energy of a photon is given by the speed of the photon, which is not the speed of the electron.
This is one of a number of energy-wave phenomena that have perplexed physicists since the dawn of time. We still don’t really know how photons work or what they do except that they can store and transmit energy to other objects. But if you’re talking about something that seems to carry energy across space and time, then you might be talking about the speed of a photon.
