Beryl

From there, the elements just get a lot more tortured as it goes. You'll see why in a minute. Chemically speaking, we'll start off with a beryl's structure. It would look something like this: Be3Al2Si6O18. Which from there, translates into this other thing right over here. You'll need to learn to read the formulas though for yourself without having me here. That's cause there may be times whether on the job that you're dealing with dangerous chemicals. Without knowing of just what you speak, it can be rather hard to figure it out for yourself. You'll also need to know this in case these things are found on the labels of the safety sheets that tell you all about the contents of course. Over here, they're a requirement along with first aid and other safety information. In other places though, there's no sorts of regulations. Therefore, a little thing like you could one day find yourself exposed to all sorts of hazardous things. Basically that's just a fancy way of saying something might be a danger to yourself I suppose. Then too, it's a recipe from which all this other fancy sorts of stuff gets through. Since, I've just discussed the prior safety component, let's see if we can follow the chemical form.

There's Be which is short for Beryllium, the element of the fourth as already shown. The three on the end refers to the number of parts in the script. Therefore, you'll be putting three parts of beryllium in the finished product compared with only two of the second and six of the third. Basically, whatever you're measurement will have to be doubled or third compared with the rest which is nearly more than all the first two parts at first. While we're at it, can you guess what Al is? That's right, it's aluminum from which its' parts would be three. What about the Si right there near the end? In case you don't recognize it, it's silicone as seen from the rest. Whateve measure you use then from this must be six parts much more. Then there's the O right there at the end. That's more than likely oxygen since few other elements match that sort of description.

Then working backwards, let's see what we'll need to do to let these things in. The oxygen one ought to be fairly simple as a good bit of stirring or bubbling would do which occurs naturally as the mixture gets heated. Perhaps you may already know the part about just adding silica or sand without anything fancy. Then from there, you'll put the aluminum into the pot with all it's fancy preparation. Just make sure you don't accidently melt down a pot to make these since some of them are already made from a molten sort of this metal. Other types of materials include stainless steel and other sorts of raw metals which are more often commonly used. Sometimes these are even combined with other types of raw materials making an alloy of sorts. That's why you should always talk with your pot-maker first to ensure these can withstand this certain high heat.

Then again, there's a few different things you'll actually have to remember. The first is that these rocks are naturally occurring near and around large types of volcanical fields. If not already known, that much from the color and shreds of the stone is abundantly clear. After some polishing though, it'll be that much more abundantly clear. Due to the color and shape and appearance, I'd say the amount of heat required is just a bit higher than what it takes in the makings of chrsolyte but of course.

From there, you'll want to add the beryllium in making the stone. I'm sure it could be done all at once and then heated. We'll want to get a feel for what this step requires first before adding it all in together. In raw form, beryllium comes in as ore pulled from the depths of the earth. Often found in mines of oil, gas, and other natural structures, what happens is the ore then gets ground into dust. The main thing though is adding the electricity which runs through the stone. You can do this as simply as adding electrical probes in to help with the shape of the stone. This added electricity settles the beryllium ore thereby changing the shape and making it a lot easier for adding other things in. You'll want to take the dust and make a sort of mix either by heating the material and then salting it down along with the water through which process the sulfate is made. It's almost like a hot pot of sorts of even a whole natural springs which are central to certain parts of the earth. You'll want to make the salt solution just enough that the sulfate is formed as seen once before. This is done by boiling just enough salt along with the water. It also serves the purpose of adding enough oxygen in. That way, it's almost like a double process through which this oxidization is applied to all three. There, that should about do it. What do you think?

Then I lifted up mine eyes, and looked, and behold a certain man clothed in linen, whose loins were girded with fine gold of Uphaz:

His body also was like the beryl, and his face as the appearance of lightning, and his eyes as lamps of fire, and his arms and his feet like in colour to polished brass, and the voice of his words like the voice of a multitude.

Daniel 10:5-6