Mars, Venus and probably Mercury, wouldn't similar elements like this be found on them, as opposed to the gas giant outer planets (except maybe on their moons)?

Mars appears to be long dead, in that regard.

I know, who knows if the periodic table of elements will be expanded once we have the ability/technology to spend time and explore on other worlds?

The heaviest nuclei decay almost exclusively by spontaneous fission. The heavier they are, the shorter their half-lives. Any heavier nuclei than those now known will have even shorter half-lives.

Their have been some suggestions, based on the 'nuclear shell model', that certain "magic numbers" of protons and neutrons might lead to more stable nuclei. The concept is sufficiently well-established that I've seen such suggestions in chemistry textbooks I've taught from, and in some SF stories as well. But "more stable" -- at least to most researchers -- means somewhat more stable than their neighbors, which have very short half-lives -- but such heavy nuclei are difficult to model with current nuclear theories, so the vote is not unanimous, and some optimists think such elements might be isolable. Personally, I think it's unlikely that we're going to find new stable elements beyond those already known. It would just require too many questionable assumptions to all line up favorably for such a search to succeed.

Discussions of stable vs unstable nuclei need to include the 'Liquid Drop Model' as well as the shell model. The LDM predicts very well which nuclei will be stable to beta-decay, with only a few exceptions due to the effects of "magic number" shells. (It's actually an interesting exercise to step through successive atomic mass numbers, A, and predict, for each one, what the atomic number(s) of the most stable nuclei will be (one for odd A, two for even A). The LDM alone usually leads to the correct prediction. Exceptions are instructive, as they always involve cases where the optimum balance between protons and neutrons is very close to a tipping point -- then, shell effects decide. Away from such tipping points, the magic numbers don't make much difference.) All sufficiently heavy nuclei spontaneously fission to form more stable nuclei; the LDM correctly predicts these decays will be more energetically "downhill" the larger the nucleus, and the trend is continuously downward as the mass number increases.

In principle, anything's possible, but some things are just much less likely than others.

After reading your post I felt like I sat through a high-level physics class.

All it takes is chance and a rogue entity of sufficient mass moving through the neighborhood to rearrange inner-planetary orbits and, oh, chance, again.

existence, is not in an of itself, an element - it is a bonded substance composed of hydrogen and oxygen - H2O that has various states, properties, and similarities. Likely that elements exist in various other states and properties as permited, known or yet unknown, or have influence on their orbits.

Sulfur is well-known to sublime readily on heating. This is why finding elemental sulfur is so surprising -- unless it was recently deposited, surface deposits of sulfur should have had time to sublime away, even at the low temps of the Martian surface.

These crystals were found inside a rock; modeling how fast sulfur vapor could have diffused through the rock could give a (very rough) estimate of how old it was. An age of thousands of years might be reasonable; I doubt one of millions of years would be. So this could be a potential clue to Mars' (relatively) recent past.