Let the analogy of two different types of liquid boil for a while before we discuss the difference between the two. First, let’s look at pure water:
Now, let’s look at salt:
Both of these materials are substances containing water. They don’t have any dissolved salts. In fact, there must be no dissolved salts in these compounds.
But salt is composed of other “solids” — calcium, magnesium, chlorine, etc. In a well-made salt, one of these dissolved salt is present in sufficient quantity to make this mixture soluble in water. When they are added to water, all the dissolved salt evaporates. If, however, water were to get too dense, the dissolved salts remain and become less soluble. If this happens, the water becomes diluted with the saline solution.
This process gives us two types of energy:
To create energy (in nature, and as we see in your world), we first have to add something.
The salt and the water become similar enough to be able to interact. In the case of salt, you can use calcium, magnesium and some chlorine. In the case of the mineral water, you can use an organic molecule called chloride.
That’s the way you make energy. If there is no such thing as energy, then we don’t need to use “energy” as we see it; we’re not moving anything — we’re just adding a substance to the mix.
But what if we add more to the mix?
What happens if we add more of what we’re trying to make? Here’s a basic example. Let’s think about making soap. If you are trying to make soap, how come you can’t make water, or salt — but not the very stuff we need?
Well, because soap is made of various compounds — some are hydrogen chloride, others are sodium chloride. In some cases, the chemicals react with each other and form salt (in liquid form) or water. The chemicals don’t have to interact; they react and give us the energy we need (the soap-making chemical).
Just as with the salt and the water examples above, when we try “to combine” two similar materials, we don’t see energy created. Instead, we get energy merely mixed in — but that energy gets converted into some other energy.
Now, you could add all the energy you needed and still not get anything. In the case of water, you might think
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