The excellent graphic novel
Prime Suspects: The Anatomy of Integers and Permutations
by Andrew Granville and Jennifer Granville, illustrated by Robert J Lewis,
(I wrote a review of this graphic novel, for SIGACT News, here.)
has an appendix, which is not in graphic-novel form, where they describe some of the math talked about in the graphic novel.
Here is a quote that intrigued me for two reasons
2 is the smallest prime factor of half of the integers,
3 is the smallest prime factor of one-sixth of the integers,
5 is the smallest prime factor of one-fifteenth of the integers,
and so forth.
Intrigue One: and so fourth ? Really? That would indicate that it is easy to know what the next fraction is. Is it easy? That depends on your definition of easy.
Intrigue Two: What is the next fraction? What is the fraction asymptotically? I worked both of these out fairly fast; however, I don't think and so forth is appropriate.
We derive the 1/15 for 5. 1/5 of all numbers have a factor of 5. Of those, only those that are \(\equiv 1,5 \pmod 6\) have 5 as the smallest prime factor. Hence \(2/6=1/3\) of those numbers have 5 as the smallest prime factor. Hence the fraction is \(1/5 \times 1/3 = 1/15\).
More generally: For all \(i\in N\) let \(p_i\) be the \(i\)th prime. What fraction of numbers have \(p_n\) as the smallest factor? \(1/p_n\) of all numbers have a factor of \(p_n\). If a number that is divisible by \(p_n\) is also \(\equiv x \pmod {p_1p_2\cdots p_{n-1}}\) where \(1\le x\le p_1\cdots p_n\) and \(x\) is rel prime to \(p_1\cdots p_n\), then that number has \(p_n\) as the smallest factor. Hence the fraction is
\(\frac{1}{p_n} \times \frac{\phi(p_1\cdots p_{n-1})}{p_1\cdots p_n}=\frac{1}{p_n} \times \frac{(p_1-1)\cdots(p_{n-1}-1)}{p_1\cdots p_{n-1}}= \frac{1}{p_n}\prod_{i=1}^{n-1} (1-\frac{1}{p_i})\)
where \(\phi\) is the Euler-phi function which, on input \(x\), returns the number of naturals in [1,n] that are relatively prime to \(n\). We have used the following well known facts: (a) if \(a,b\) are rel prime then \(\phi(ab)=\phi(a)\phi(b)\), and (b) if \(p\) is prime then \(\phi(p)=p-1\) (this is obvious).
The expression
\(\frac{1}{p_n} \times \frac{(p_1-1)\cdots(p_{n-1}-1)}{p_1\cdots p_{n-1}}\)
is good for exact calculation. Let's do one!
The fraction of numbers that have 7 as their least prime factor is
\( \frac{1}{7}\times \frac{1\times 2\times 4}{2\times 3\times 5}= \frac{4}{105} \)
From the first three terms \( \frac{1}{2}, \frac{1}{3}, \frac{1}{15} \) I do not think that and so fourth would make anyone think the next term was \(\frac{4}{105}\).
But what is the fraction asymptotically?
ChatGPT tells me (and I believe it) that
\( \prod_{i=1}^{n} (1-\frac{1}{p_i}) \sim \frac{e^{-\gamma}}{\ln p_n} \)
where \(\gamma\) is the Euler-Mascheroni constant, roughly 0.5772 (see here for the Wikipedia entry on that constant).
Hence we get that the fraction of numbers that have \(p_n\) as their smallest prime factor is
\(\frac{1}{p_n} \prod_{i=1}^{n-1} (1-\frac{1}{p_i}) \sim\frac{1}{p_n} \frac{e^{-\gamma}}{\ln p_{n-1}} \)
Wolfram Alpha tells me (and I believe it) that
\(e^{-0.5772}\sim 0.56146\).
Hence we give our final approx for the fraction of numbers that have \(p_n\) as their least prime factor as
\(\frac{0.56146}{p_n\ln(p_{n-1})}\)
I don't think this qualifies as and so forth.