Confusing chemical names: why do some sound so similiar?

It’s the end of March as I write this and, here in the UK at least, things are starting to feel a little bit hopeful. We’ve passed the spring equinox and the clocks have just gone forward. Arguments about the rights and wrongs of that aside, it does mean daylight late into the day, which means more opportunities to get outside in the evenings. Plus, of course, COVID-19 vaccines are rolling out, with many adults having had at least their first dose.

Some COVID-19 vaccines contain polyethylene glycol (PEG), a safe substance found in toothpaste, laxatives and other products, according to Science magazine and health expertsAh, yes. Speaking of vaccines… a couple of weeks ago I spotted a rather strange item trending on Twitter. The headline was: “Some COVID-19 vaccines contain polyethylene glycol (PEG), a safe substance found in toothpaste, laxatives and other products, according to Science magazine and health experts.”

Apart from being a bit of mouthful, this seemed like the most non-headline ever. And also, isn’t it the kind of thing that might raise suspicions in a certain mind? In a, “yeah, and why do they feel the need to tell us that, huh” sort of way?

Why on earth did it even exist?

A little bit of detective work later (by which I mean me tweeting about it and other people kindly taking the time to enlighten me) and I had my answer. The COVID-19 sceptic Alex Berenson had tweeted that the vaccine(s) contained antifreeze. Several people had immediately responded to say that, no, none of the vaccine formulations contain antifreeze. Antifreeze is ethylene glycol, which is definitely not the same thing as polyethylene glycol.

I’m not going to go much further into the vaccine ingredients thing, because actual toxicologists weighed in on that, and there’s nothing I (not a toxicologist) can really add. But this did get me thinking about chemical names, how chemists name compounds, and why some chemical names seem terrifyingly long while others seem, well, a bit silly.

A lot of the chemical names that have been around for a long time are just… names. That is, given to substances for a mixture of reasons. They do usually have something to do with the chemical makeup of the thing in question, but it might be a bit tangential.

formic acid, HCOOH, was first extracted from ants

For example, formic acid, HCOOH, takes its name from the Latin word for ant, formica, because it was first isolated by, er, distilling ant bodies (sorry, myrmecologists). On the other hand limestone, CaCO3, quicklime, CaO, and limewater, a solution of Ca(OH)2, all get their names from the old English word lim, meaning “a sticky substance,” which is also connected to the Latin limus, from which we get the modern word slime — because lime (mostly CaO) is the sticky stuff used to make building mortar.

The trouble with this sort of system, though, is that it gets out of control. The number of organic compounds listed in the American Chemical Society‘s index is in excess of 30 million. On top of which, chemists have an annoying habit of making new ones. Much as some people might think forcing budding chemists to memorise hundreds of thousands of unrelated names is a jolly good idea, it’s simply not very practical (hehe).

It’s the French chemist, Auguste Laurent, who usually gets most of the credit for deciding that organic chemistry needed a system. He was a remarkable scientist who discovered and synthesised lots of organic compounds for the first time, but it was his proposal that organic molecules be named according to their functional groups that would change things for chemistry students for many generations to come.

Auguste Laurent (image source)

Back in 1760 or so, memorising the names of substances wasn’t that much of a chore. There were half a dozen acids, a mere eleven metallic substances, and about thirty salts which were widely known and studied. There were others, of course, but still, compared to today it was a tiny number. Even if they were all named after something to do with their nature, or the discoverer, or a typical property, it wasn’t that difficult to keep on top of things.

But over the next twenty years, things… exploded. Sometimes literally, since health and safety wasn’t really a thing then, but also figuratively, in terms of the number of compounds being reported. It was horribly confusing, there were lots of synonyms, and the situation really wasn’t satisfactory. How can you replicate another scientist’s experiment if you’re not even completely sure of their starting materials?

In 1787 another French chemist, Guyton de Morveau, suggested the first general nomenclature — mostly for acids, bases and salts — with a few simple principles:

  • each substance should have a unique name, as short and specific as possible
  • the name should reflect what the substance consisted of, that is, describe its “composing parts”
  • unknown substances should be assigned names with no particular meaning, being sure not to suggest something false about the substance (if you know it’s not an acid, for example, don’t name it someinterestingname acid)
  • new names should be based on old languages, such as Latin

His ideas were accepted and adopted by most chemists at the time, although a few did attack them, claiming they were “barbarian, incomprehensible, and without etymology” (reminds me of some of the arguments I’ve had about sulfur). Still, his classification was eventually made official, after he presented it to the Académie des Sciences.

Chemists needed a naming system that would allow them to quickly identify chemical compounds.

However, by the middle of the 1800s, the number of organic compounds — that is, ones containing carbon and hydrogen — was growing very fast, and it was becoming a serious problem. Different methods were proposed to sort through the messy, and somewhat arbitrary, accumulation of names.

Enter Auguste Laurent. His idea was simple: name your substance based on the longest chain of carbon atoms it contains. As he said, “all chemical combinations derive from a hydrocarbon.” There was a bit more to it, and he had proposals for dealing with specific substances such as amines and aldehydes, and of course it was in French, but that was the fundamental idea.

It caused trouble, as good ideas so often do. Most of the other chemists of the time felt that chemical names should derive from the substance’s origins. Indeed, some of the common ones that chemistry professors are clinging onto today still do. For example, the Latin for vinegar is acetum, from which we get acetic acid. But, since organic chemistry was increasingly about making stuff, it didn’t entirely make sense to name compounds after things they might have come from, if they’d come from nature — even when they hadn’t.

So, today, we have a system that’s based on Laurent’s ideas, as well as work by Jean-Baptiste Dumas and, importantly, the concept of homology — which came from Charles Gerhardt.

Homology means putting organic compounds into “families”. For example, the simplest family is the alkanes, and the first few are named like this:

Like human families, chemical families share parts of their names and certain characteristics.

The thing to notice here is that all the family members have the same last name, or rather, their names all end with the same thing: “ane”. That’s what tells us they’re alkanes (they used to be called paraffins, but that’s a name with other meanings — see why we needed a system?).

So the end of the name tells us the family, and the first part of the name tells us about the number of carbons: something with one carbon in it starts with “meth”. Something with five starts with “pent”, and so on. We can go on and on to much bigger numbers, too. It’s a bit like naming your kids by their birth order, not that anyone would do such a thing.

There are lots of chemical families. The alcohols all end in “ol”. Carboxylic acids all end in “oic acid” and ketones end in “one” (as in bone, not the number). These endings tell us about certain groups of atoms the molecules all contain — a bit like everyone in a family having the same colour eyes, or the same shaped nose.

A chemist that’s learned the system can look at a name like this and tell you, just from the words, exactly which atoms are present, how many there are of each, and how they’re joined together. Which, when you think about it, is actually pretty awesome.

Which brings me back to the start and the confusion of glycols. Ah, you may be thinking, so ethylene glycol and polyethylene glycol are part of the same family? Their names end with the same thing, but they start differently?

Well, hah, yes and no. You remember a moment ago when I said that there are still some “common” names in use, that came from origins — for example acetic acid (properly named ethanoic acid)? Well, these substances are a bit like that. The ending “glycol” originates from “glycerine” because the first ones came from, yes, glycerine — which you get when fats are broken down.

Polyethylene glycol (PEG) is a polymer, with very different properties to ethylene glycol (image source)

Things that end in glycol are actually diols, that is, molecules which contain two -OH groups of atoms (“di” meaning two, “ol” indicating alcohol). Ethylene glycol is systematically named ethane-1,2-diol, from which a chemist would deduce that it contains two carbon atoms (“eth”) with alcohol groups (“ol”) on different carbons (1,2).

Polyethylene glycol, on the other hand, is named poly(ethylene oxide) by the International Union of Pure and Applied Chemistry (IUPAC), who get the final say on these things. The “poly” tells us it’s a polymer — that is, a very long molecule made by joining up lots and lots of smaller ones. In theory, the “ethylene oxide” bit tells us what those smaller molecules were, before they all got connected up to make some new stuff.

Okay, fine. So what’s ethylene oxide? Well, you see, that’s not quite a systematic name, either. Ethylene oxide is a triangular-shaped molecule with an oxygen atom in it, systematically named oxirane. Why poly(ethylene oxide), and not poly(oxirane), then? Mainly, as far as I can work out, to avoid confusion with epoxy resins and… look, I think we’ve gone far enough into labyrinth at this point.

The thing is, polyethylene glycol is usually made from ethylene glycol. Since everyone tends to call ethylene glycol that (and rarely, if ever, ethane-1,2-diol), it makes sense to call the polymer polyethylene glycol. Ethylene glycol makes polyethylene glycol. Simple.

Plastic bags are made from polythene, which has very different properties to the ethene that’s used to make it.

Polymers are very different to the molecules they’re made from. Of course they are, otherwise why bother? For example, ethene (also called ethylene, look, I’m sorry) is a colourless, flammable gas at room temperature. Poly(ethylene) — often just called polythene — is used to make umpteen things, including plastic bags. They’re verrrrry different. A flammable gas wouldn’t be much use for keeping the rain off your broccoli and sourdough.

Likewise, ethylene glycol is a colourless, sweet-tasting, thick liquid at room temperature. It’s an ingredient in some antifreeze products, and is, yes, toxic if swallowed — damaging to the heart, kidneys and central nervous system and potentially fatal in high enough doses. Polyethylene glycol, or PEG, on the other hand, is a solid or a liquid (depending on how many smaller molecules were joined together) that’s essentially biologically inert. It passes straight through the body, barely stopping along the way. In fact, it’s even used as a laxative.

So the headlines were accurate: PEG is “a safe substance found in toothpaste, laxatives and other products.” It is non-toxic, and describing it as “antifreeze” is utterly ridiculous.

In summary: different chemicals, in theory, have nice, logical, tell-you-everything about them names. But, a bit like humans, some of them have obscure nicknames that bear little resemblance to their “real” names. They will insist on going by those names, though, so we just need to get on with it.

The one light in this confusingly dark tunnel is the internet. In my day (croak) you had to memorise non-systematic chemical names because, unless you had a copy of the weighty rubber handbook within reach, there was no easy way to look them up. These days you can type a name into Google (apparently other search engines are available) and, in under a second, all the names that chemical has ever been called will be presented to you. And its chemical formula. And multiple other useful bits of information. It’s even possible to search by chemical structure these days. Kids don’t know they’re born, I tell you.

Anyway, don’t be scared of chemical names. They’re just names. Check what things actually are. And never, ever listen to Alex Berenson.

And get your vaccine!

If you’re studying chemistry, have you got your Pocket Chemist yet? Why not grab one? It’s a hugely useful tool, and by buying one you’ll be supporting this site – it’s win-win! If you happen to know a chemist, it would make a brilliant stocking-filler! As would a set of chemistry word magnets!

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Want something non-sciency to distract you from, well, everything? Why not check out my fiction blog: the fiction phial.


Are you ok? You look a little flushed.

PrintYesterday was World Toilet Day (yes, really). This is actually an admirable campaign by WaterAid to raise awareness of the fact that one in three people around the world don’t have access to a safe and private toilet. This, of course, leads to unsanitary conditions which results in the spread of infection and disease. You’ve probably never given it a second thought, but loos literally save lives.


Has the TARDIS’ replicator function gone funny?

So, with the topic of toilets in mind, I started thinking about chemical loos. If you live in the UK, the name Portaloo ® will probably spring to mind. This has practically become a generic word for a portable toilet, but it is (like Hoover, Sellotape and others) actually a brand name. I’m told that in America they call them porta-pottys or honey-buckets, which I rather like. In any case, all the chemicals and plastic make them seem like modern inventions, surely?

Actually, not at all. The idea of a self-contained, moveable toilet that you can pick up and take from place to place may be newer, but people have been using chemical toilets for hundreds of years. For example after, ahem, ‘business’ had been completed in an an old-fashioned wooden outhouse – basically a tall box built over a hole in the ground – the user would sprinkle a little lye or lime down the hole to help with the smell.


Don’t get sodium hydroxide on the toilet seat.

Both of these are strongly basic chemicals. Lye is either sodium hydroxide or potassium hydroxide, and lime is calcium oxide. Both mix with water to form extremely corrosive, alkaline solutions and, incidentally, give out a lot of heat in the process. Both are very damaging to skin. These were the days before health and safety; whatever you did, you had to try not to spill it on the seat.

Urea, a key chemical in urine, reacts with strong alkalis in a process known as alkaline hydrolysis. This produces ammonia, which is pretty stinky (if rather tough on the lungs), so if nothing else that helped to cover up other smells. Ammonia also kills some types of bacteria (which is one reason it’s popular in cleaning products). Flies generally don’t like high concentrations of it either, so that’s another plus.

Alkalis also have another effect in that decomposition of human waste is pH dependent; it works better in acidic conditions. Adding lye or lime raises the pH and slows down this decomposition. On top of this (literally) both lime and lye are hygroscopic: they absorb water. This keeps moisture down and allows a solid ‘crust’ to form on the surface of the waste, making it difficult for any volatile, smelly chemicals to escape. Lovely.

Bleach and ammonia could result in a rocket up your...

Bleach and ammonia could result in a rocket up your…

One word of caution: it’s very, very important you don’t try to clean such an outhouse with any kind of bleach. Bleach, which contains sodium hypochlorite, reacts with ammonia to form hydrogen chloride, chlorine gas and chloramine. None of which are good for your health. Even more dramatically (if this is more dramatic than death – you decide) if there’s lots of ammonia you might get liquid hydrazine, which is used in rocket fuels because it’s explosive. Who knew that toilet chemistry could also be rocket science?

But you don’t find buckets of lye in modern chemical toilets (although, apparently, there are still some people out there using it). So what’s in there? At one time, formaldehyde, otherwise known as methanal, was common. You probably recognise it as embalming fluid; the stuff that Damien Hirst floated that shark in. It’s an extremely effective preservative. Firstly, it kills most bacteria and fungi and destroys viruses, and secondly it causes primary amino groups in proteins to cross-link with other nearby nitrogen atoms, denaturing the proteins and preventing them from breaking down.


Don’t worry, this won’t appear in your chemical toilet.

Interestingly, whilst definitely toxic in high concentrations, formaldehyde is a naturally-occuring chemical. It’s found in the bloodstream of animals, including humans, because it’s involved in normal metabolism. It also appears in fruits and vegetables, notably pears, grapes and shiitake mushrooms. The dose, as they say, makes the poison. I mention this because there are certain campaigners out there who insist it must be completely eliminated from everything, something which is entirely unecessary not to mention probably impossible (just for the hell of it, I’m also going to point out here that an average pear contains considerably more formaldehyde than a dose of vaccine).

All that said, because formaldehyde is extremely toxic in high concentrations, and because it can interfere with the breakdown processes in sewage plants (because it destroys bacteria), formaldehyde isn’t used in toilets so much anymore. In fact, many of the mixtures on sale are explicitly labelled “formaldehyde-free”. Modern formulations are enzyme-based and break down waste by biological activity. They are usually still dyed blue (if you work your way though the colour spectrum, it’s probably the least offensive colour), but usually using food-grade dye. As a result, what’s left afterwards is classed as sewage rather than chemical waste, making it easier to deal with.

Toilet twinning So, this has been brief tour around the fascinating world of toilet chemistry. You’d never have guessed there was so much to it, would you? Now, have you considered twinning your toilet?