I type em dashes as double hyphens. Sometimes the software resolves them to a true em dash, but sometimes not.

I never use hyphens where em dashes would be correct.

I do have issues determining when a two-word phrase should or shouldn't be hyphenated. It surely doesn't help that I grew up in a bilingual English/German household, so that my first instinct is often to reject either option, and fully concatenate the two words instead.

(Whether that last comma is appropriate opens a whole other set of punctuation issues ... and yes, I do tend to deliberately misuse ellipses for effect.)

My English professor criticized me for allegedly excessive use of em dashes in 1973.

Once I started self-publishing in the 1990s, I disregarded her opinion.

ab and (-a)(-b) can each be quickly proved to be the additive inverse of (-a)b. So they equal each other. No intermediate theorems are really needed.

I am not sure how you can prove this more "quickly". Trying to do it any more quickly involves claiming some result (no matter how trivial) that is not directly present in the ring axioms. But the whole point of this post is to derive everything strictly from first principles, using nothing beyond the ring axioms themselves.

Here is your argument elaborated step by step.

STEP 1: First we want to show that ab is the additive inverse of (-a)b. This is Theorem 3 of the post.

STEP 2: Next we want to show that (-a)(-b) is the additive inverse of (-a)b. This follows similarly to the proof of Theorem 3: (-a)(-b) + (-a)(b) = (-a)(-b + b) = (-a)(0) and (-a)(0) = 0 by Theorem 2 of the post.

But nothing in the ring axioms directly says that the above results mean ab and (-a)(-b) must be equal. How do we know for sure that ab and (-a)(-b) are not two distinct additive inverses of (-a)b?

THEOREM 5: We now prove the uniqueness of additive inverse of an element from the ring axioms. Let b and c both be additive inverses of a. Therefore b = b + 0 = b + (a + c) = (b + a) + c = 0 + c = c.

Now from Steps 1 and 2, and Theorem 5, it follows that ab = (-a)(-b).

So what did we save in terms of intermediate theorems? Nothing! We no longer need Theorem 1 (inverse of inverse) of the post. But now we introduced Theorem 5 (uniqueness of additive inverse). We have exactly the same number of intermediate theorems with your approach.

I was one of several math grad students who started at Harvard at age 16 or 17 aroud the same time. Ofer Gabber and Ran Donagi went on to conventional academic math careers. I took a less straightforward career path.

But I was offered an assistant professorship at the Kellogg School of Business at age 21, and have often wondered whether I should perhaps have taken that, or else the research position I was offered at RAND.

I was told that a book published in honor of Oscar Zariski's 80th birthday included a paper by Oscar Zariski, either proving or at least making progress on a longstanding conjecture by Oscar Zariski.

I was in the relevant department at the time (Harvard math), but I wasn't much of an algebraic geometer, so I took that at face value without probing for details.

> Socrates had a skeptical view of written language, preferring oral communication and philosophical inquiry. This perspective is primarily presented through the writings of his student, Plato, particularly in the dialogue Phaedrus.

He did not. You should read the dialogue.

> I confirmed that from my own memory via a Google AI summary, quoted verbatim above.

This is the biggest problem with LLMs in my view. They are great at confirmation bias.

In Phaedrus 257c–279c Plato portrays Socrates discussing rhetoric and the merits of writing speeches not writing in general.

"Socrates: Then that is clear to all, that writing speeches is not in itself a disgrace.

Phaedrus: How can it be?

Socrates: But the disgrace, I fancy, consists in speaking or writing not well, but disgracefully and badly.

Phaedrus: Evidently."

I mean, writing had existed for 3 millennia by the point this dialogue was written.

It is both exciting how far we got and depressing how far we didn't.

I stopped reading early, when the article said that in the 1970s one big relational database did everything.

In fact, relational databases did nothing in the 1970s. They didn't even exist yet in commercial form.

My first prediction as an analyst from 1982 onwards was that "index-based" DBMS would take over from linked-list DBMS and flat files. (That was meant to cover both inverted-list and relational systems; I expected inverted-list DBMS to outperform relational ones for longer than they did.)

Robert Heinlein's "... And he built a crooked house" is both hilarious and mathematical, although perhaps in different parts of the same story.

https://homepages.math.uic.edu/~kauffman/CrookedHouse.pdf

Like many classic science fiction "novels", including Foundation, Poul Anderson's Operation Chaos is really a collection of linked novellas.

The last one has the hero and heroine recruiting the spirit of Lobachevsky to help them recover their daughter from non-Euclidean hell.

Mathematical fiction is tough, because of the problems with "mathematical counterfactuals". Why not go with mathematical poetry instead? There are nice sections of same in the Clifton Fadiman anthologies. The first of these is also from The Space Child's Mother Goose. (All from memory, so please pardon any errors.)

---------------

Three jolly sailors from Blandon-on-Tyne

Went to sea in a bottle by Klein

They found the view exceedingly dull

For the sea was entirely contained in the hull.

---------------

There was a young lady named Bright

Who traveled much faster than light

She departed one day

In a relative way

And returned the previous night.

-------------

There once was a fencer named Fisk

Whose movements were agile and brisk

So quick was his action

The Lorentz contraction

Diminished his sword to a disk.

--------------

(There's also a bawdy version of that somewhere, referring to a different "sword".)

My favorite:

"Very well. Let's have a love poem, lyrical, pastoral, and expressed in the language of pure mathematics. Tensor algebra mainly, with a little topology and higher calculus, if need be. But with feeling, you understand, and in the cybernetic spirit."

"Love and tensor algebra? Have you taken leave of your senses?" Trurl began, but stopped, for his electronic bard was already declaiming:

Come, let us hasten to a higher plane,

Where dyads tread the fairy fields of Venn,

Their indices bedecked from one to n,

Commingled in an endless Markov chain!

Come, every frustrum longs to be a cone,

And every vector dreams of matrices.

Hark to the gentle gradient of the breeze:

It whispers of a more ergodic zone.

In Riemann, Hilbert or in Banach space

Let superscripts and subscripts go their ways.

Our asymptotes no longer out of phase,

We shall encounter, counting, face to face.

I'll grant thee random access to my heart,

Thou'lt tell me all the constants of thy love;

And so we two shall all love's lemmas prove,

And in our bound partition never part.

For what did Cauchy know, or Christoffel,

Or Fourier, or any Boole or Euler,

Wielding their compasses, their pens and rulers,

Of thy supernal sinusoidal spell?

Cancel me not - for what then shall remain?

Abscissas some mantissas, modules, modes,

A root or two, a torus and a node

The inverse of my verse, a null domain.

Ellipse of bliss, converge, O lips divine!

The product of our scalars is defined!

Cyberiad draws nigh, and the skew mind

Cuts capers like a happy haversine.

I see the eigenvalue in thine eye,

I hear the tender tensor in thy sigh.

Bernoulli would have been content to die,

Had he but known such a^2 cos 2 phi!

   -- Cyberiad. Stanislaw Lem

I'd completely forgotten that one!!

I just recall the (non-mathematical) poem about the haircut.

Certainly that section generally comes more to mind these days in the age of LLMs ..