UNsolved problems in chemistry.

[1] Superconductors; this is a quest to find the ways to make super conductors. there are certain compounds or materials in the earth that can deliver extremely high temperatures of heat without melting. of course, the ideal would be to find why they do this?

The strongest conductor would be as water, as it has a triangular gluon makeup, and, this means that there is no friction between the points of the gluon. this means that they travel from far away in the atom to close quarters - the question is why they do not push away from each other as they meet, but the answer is that the force of 'attractive friction' is so great it pulls them together even though the gluon is pushing away, being of similar charge. then, there is the fact that the water will be polarized to find itself, being attracted to itself as all materials are. this is because of equal charges, in all senses of the word, find 'the same space' to be beneficial for both or more sets of water drops.

So, what makes something a conductor? the conductors will conduct heat because they are so charged - the further you go down the elemental table, the more conductive things get, as, they are denser, holding things together becomes easier the denser they are. this is because the denser the material, the more electrons they have, or, protons, to allow for 'excess heat.' due to the closeness of the materials bonds, they will transfer the heat on those spinning things we call protons and electrons, as electrons bond, the protons carry the charge over the bond to the next bond, sending heat all over the materials.

Now, if we were to say these super conductors are denser, are they? if they were denser, then they would be extremely hard to cut and mold. they say these are ceramics, the super conductors, so will chip and break easily.

To find the perfect conductors, we need to di what was done with graphene - one atom of carbon could be replaced by one atom of steel, or other materials?

... Of course, to maximize the potential, the whole material could be made of overlapping materials like these, to find the best combination of materials.

If we were particularly shrewd, we could combine layers of the atoms of water? these made of single atoms separately could achieve wonders!

[3] Feynmanium; is this the last possible element with an atomic number of 137?

I think the need for the electron to move faster than the speed of light is impossible, as, the photon carrying it will need t go faster than it goes. of course, if it is 'pushed' forwards by the bulk of photons and electrons behind it, it will go faster. this means that the limit is limitless as far as we know, but, it would be impractical to just keep pushing, yes?

If we were to use displacement, it would go slower per capita than the rate it should be going, but moving faster none the less.

[4] "How can electromagnetic energy (photons) be efficiently converted to chemical energy? For instance, can water be efficiently split to hydrogen and oxygen using solar energy?"

If we want to split water and hydrogen into hydrogen and oxygen, we need heat. this will dissolve the water into a gas, and, the gas can be filtered, you could say. if we want to split it into other elements, being hydrogen and oxygen, we need to use magnetism to hover over the water to pull one or the other out, by using polarizing charges for one or the other. the water will be lifted out of the 'container' and the other one will be sucked back down using a similar yet differently charged magnetic force.

But that is water. if we want to split things using photons, we need to use layers of photons which 'come together.' this would make a 'divider,' like a knife dividing different clumps of cheese. this would mean that the photons, which are always moving, merely being replaced by others traveling the same route, would need to carry the things with them, or leave them 'divided.'

If you want to carry them with you, you need to use friction to attract materials to them. this would mean that you need to use a photon scheme like a cupped line of light shining onto the materials, like a magnifying glass - use the ideals of a magnifying glass if you ask me! this would be where the light is focused on one point, and, then begins to divide materials. this is due to many atoms displacing others, due to charges, of course, and, them finding the same spaces hospitable.

[5] Is an abiologic origin of chirality as is found in (2R)-2,3-dihydroxypropanal (D-glyceraldehyde), and also in amino acids, sugars, etc., possible?

The possibility of chirality not being found in other things is demonstrated to be true as things mix. this is because, if they did not mix, then there would be no mixing of the chemicals that need to mix, for example, for producing lungs or eyes. this very reasonable logic means that if we did not have a double on the outside, there would be no attempt at a double on the inside, and, if there was no double on the inside, there would be no attempt of a double on the outside, of course. if we were to look at cell division, we would see that there are identical cells coming from one cell, of course.

[6] Why are accelerated kinetics observed for some organic reactions at the water-organic interface?

This is due to the oxygen and hydrogen being attracted to the makeup of the organic materials. these exchanges of energy stem from the water of the inside of the biomass being drawn to the water on the outside, of course. most organic things are made of a great percentage of water, so will merely 'mix.' the reason it is accelerated is because the present placing of blood and other things is ideal for the water too.

[7] What is the origin of the energy barrier to bond rotation (e.g., in ethane), simple steric hindrance, hyperconjugation, or another explanation?

This is due to not being able to occupy the same space at the same time. this is because they will be made of similar charge, maybe it is 'hyper' because of metallic constituents, as, some liquids are conductors. this means that each bond is thicker, because of molecular bonding, due to the inside of the element needing to remain as it is, because of the makeup of the mixture, then the mixture will be slower to mix, ad, it is behaves like an atom with particles behaving the way they do with a dense material.

If you want to know about chemistry try askign yuour chemistry teacher

[8] The alpha effect is where lone pair electrons create a accelerated base mixing effect. the base is of course an element of some sort, and, i suspect that it is because the base is liquid and metal, leading to two conductors being in the same mixture, leading to the actual liquid that the element is mixing with being the conductor - the flakes of electrons carry the charge faster than the metals - even though the metals are also considered conductors - because their relays are based on the mixture being one whoe, instead of a few flakes of metal.

Then, the mixture mixes the whole of the element with other things, due to 'dilution.' the diluting characteristics of the mixture are carried faster because the negative atom is active - it 'sucks' or 'pushes.' this is where any activity comes from, the negative side of things, as, the negative charge will seek positive stabilizers, like a fire spreading, looking for the balance it seeks. in liquids, this would be where the elements rise to the top of the other less dense liquids, as they will find this is like hot air and cold air - obviously the other material being more dense has more orbitals and electrons, which means that it will rise.

Likewise, the denser the material, the more it will find the 'speed' to travel. the closer they are to the center, the less they have to travel to rotate, as, it is a shorter circumference, as, it is rotating the full circle or 360 degrees at a shorter range.

[9] "What is the nature of strong gold-chalcogens in thiols and other organochalcogens (i.e., sulfur and higher chalcogen-containing organic compounds)?"

You find gold inside the thiols as the odor is a gas, leading to a less dense element. these smells make the gold as it is a flexible metal, and, the smells are gaseous, leading to a lot of old air circulating, being fresh and generating gold, as the gold is 'old stuff,' being fed fresh air by the odors.