I am trying to understand the upper bound on factorions (in base $10$). The Wikipedia page says:
"If $n$ is a natural number of $d$ digits that is a factorion, then $10^{d − 1} \le n \le 9!d$. This fails to hold for $d \ge 8$ thus $n$ has at most $7$ digits, and the first upper bound is $9,999,999$. But the maximum sum of factorials of digits for a $7$ digit number is $9!7 = 2,540,160$ establishing the second upper bound."
Please explain this to me in simple terms, precisely the first part $10^{d − 1} \le n \le 9!d$.
By definition, $n$ is the sum of the factorials of its digits. Since each digit of $n$ is at most 9, this can be at most $9!\cdot d$, where $d$ is the number of digits of $n$:
If $n$ is a factorion: $$ n=d_1d_2\cdots d_d\quad\Rightarrow\quad n= d_1!+\,d_2!\,+\cdots+ \,d_d!\le \underbrace{9!+\,9!+\,\cdots+\, 9!}_{d -\text{terms}}\le9!\cdot d $$
The lower bound is trivial, since $n$ has $d$ digits, it must be at least $10^{d-1}$.