Editing 2913: Periodic Table Regions

| Weird dirt || Lighter alkali and alkaline earth metals || Lithium, Beryllium || Lithium and beryllium, as some of the lightest elements, have unusual properties compared to heavier metals. Lithium, for instance, is the least dense metal on the periodic table, and is used in applications such as [https://www.rsc.org/periodic-table/element/3/lithium rechargeable batteries] and as a {{w|Lithium_(medication)|psychiatric medication}}. Beryllium is both toxic and transparent to x-rays, but also keeps its shape and stiffness over a wide range of temperatures, leading to its use in the primary mirrors of the [https://webb.nasa.gov/content/observatory/ote/mirrors/index.html#3 James Webb Space Telescope]. It was also used in F1, both in brake calipers and {{w|Beryllium#Applications|internal engine parts}}, before being outlawed (due to its toxicity). Also, {{w|Beryllium#Nuclear_applications|both}} {{w|Lithium#Nuclear|elements}} have nuclear applications.

| Ends in a number, let it slumber. Ends in a letter, not much better. || Heavier alkali and alkaline earth metals || Rubidium, Strontium, Cesium<!-- Let's not have an edit war, after all, Randall is American. Also title text's spelling. -->, Barium, Francium, Radium || Highly reactive metals, some of which are commonly used as radioactive isotopes (which are known by a number; e.g. radium-223).<br/>The title text mentions cesium-133 and cesium-134, with the former being the only stable isotope of cesium. The phrase, "cesium-133, let it be," in the title text is a reference to the mnemonic used to remind one how to identify and to avoid {{w|poison ivy}}: "leaves of 3, let it be". The joke is that these elements are so aggressively reactive that even where stable isotopes exist, they're incredibly dangerous to handle (ie, "not much better" than the radioactive ones).

| Boring alloy metals. Probably crucial to the spark plug industry or something. (But one of them is radioactive so stay on your toes.) || The left transition metals || Scandium, Titanium, Vanadium, Chromium, Manganese, Yttrium, Zirconium, Niobium, Molybdenum, Technetium, Ruthenium, Hafnium, Tantalum, Tungsten, Rhenium, Osmium || These elements tend not to be very well known to the general public, since they're rarely primary components in anything a typical person would encounter. Nonetheless, they're used as constituents (sometimes as a small but vital trace) in alloys with specific uses, including {{w|stainless steel}}, {{w|Electric light|bulb filaments}} and {{w|Superconductivity|superconductors}}.<br/>A {{w|spark plug}} may use {{w|austenitic stainless steel}}, which includes chromium and (in some cases) molybdenum, for heat and oxidation resistance.<br/>{{w|Technetium}} is the lightest element that has no stable isotope and is thus radioactive. Technetium is commonly used in medical imaging.

| Regular metals || The top transition metals || Titanium, Manganese, Iron, Cobalt, Nickel, Copper, Zinc, Aluminum<!-- Let's not have an edit war, after all, Randall is American. -->, Silicon || Commonly known metals (and one metalloid, silicon). These all have important uses in construction and other major industries. Titanium is extremly light weight and creates bright white sparks. Iron is a common building material. Its used in almost everything from bridges to buildings. Nickel and Zinc are both found in American coins (Zinc makes up 97.5% of the {{w|Penny (United States coin)|penny}}). Copper is part of Gold's family and is used mostly in wires because of its conducting properties. Aluminum is also extremly light weight like Titanium. Its used in high stress but light weight applications such as bike frames and airplanes.  

| $$$$ || The platinum group || Rhodium, Palladium, Silver, Osmium, Iridium, Platinum, Gold || Rare and highly prized metals. The most expensive of these, osmium, is worth about $1,600 per gram as of when the comic was posted. Gold, silver and platinum are famous for being precious metals, and are commonly used in jewelry.

| Very specific health problems || Iodine and Radon || Iodine, Radon || {{w|Radon}} gas is formed in the radioactive decay series of uranium and thorium, which occur in trace levels in many common minerals. The gravel and concrete used in construction include such minerals, and the radon is released into air via pores and cracks in the stone and concrete. The relatively poor ventilation in underground spaces such as basements and cellars can cause the radon to accumulate rather than being released into the environment. Eventually, the radon itself decays into other elements, which are also radioactive. Radon is chemically very inert and doesn't bind to anything, but it can still be inhaled, and its daughter elements can bind to dust particles. The radioactive materials, when inhaled, can cause damage to cells, especially in the lungs, with lung cancers as a possible long-term consequence. Iodine is a required nutrient that humans need in trace amounts to remain healthy, with an iodine deficiency typically causing thyroid problems such as goitre. Radioactive iodine is easily taken into the body, deliberately to counteract hyperthyroidism (by giving the thyroid gland radiation damage) or uncontrollably due to exposure to material in nuclear fallout/accidents. Giving high doses of 'normal' iodine would ideally flush out the problematic isotope. Even comparing the two radioactive effects, these two specific health problems are entirely unrelated, and it is only by coincidence that they are corner-to-corner on the periodic table.

Lawful Neutral is a reference to the {{w|Dungeons & Dragons}} alignment chart, which gives moral categories for characters. The chart goes from Lawful to Chaotic on one axis, and Good to Evil on another. Lawful Neutral means following the law without any bias towards Good or Evil, which could be exemplified by the unreactivity of the noble gases. See also: [[2251: Alignment Chart Alignment Chart]].

| Don't bother learning their names – they're not staying long || Astatine and Period 7 from Rutherfordium onwards || Astatine, Rutherfordium, Dubnium, Seaborgium, Bohrium, Hassium, Meitnerium, Darmstadtium, Roentgenium, Copernicum, Nihonium, Flerovium, Moscovium, Livermorium, Tennessine, Oganesson || These elements are hard to produce in large quantities and decay within hours or less... in some cases, milliseconds. (Their names haven't exactly been stable, either, with previous multiple systems of placeholder names. For example, dubnium has been called nielsbohrium, hahnium, joliotium, unnilpentium, and eka-tantalum.)

| Whoever figures out a better way to fit these up there gets the next Nobel Prize || The internal transition metals || Lanthanum, Cerium, Praseodymium, Neodymium, Promethium, Samarium, Europium, Gadolinium, Terbium, Dysprosium, Holmium, Erbium, Thulium, Ytterbium, Lutetium, Actinium, Thorium, Protactinium, Uranium, Neptunium, Plutonium, Americium, Curium, Berkelium, Californium, Einsteinium, Fermium, Mendelevium, Nobelium, Lawrencium|| The {{w|lanthanide}}s and {{w|actinide}}s are usually placed disconnected from the main periodic table, largely because putting then where they "should" be would [https://ptable.com/image/periodic-table-wide.svg make the chart very long]. Other {{w|types of periodic tables}} that arrange the elements exist; with the seventh period filled out the hunt is on for the eighth period which is expected to {{w|Extended periodic table|contain an extra 18 groups (columns)}}, making a redesign even more prudent than ever.