Let᾽s start with some definition.
Definition. Let $x\in(0,\infty)$. The decimal part of the decadic logarithm of $x$ is called mantissa of $x$ and we denote it as
$$\text{m}(x)=\log_{10}x-\lfloor\log_{10}x\rfloor.$$
Observe first that $n!$ starts with 2020 if and only if
$$
\text{m}(n!)=\log_{10}(n!)-\lfloor\log_{10}(n!)\rfloor\in [\log_{10}2.020,\log_{10}2.021).
$$
Hence, suffices to show that the values of the sequence
$$a_n=\text{m}(n!)=\log_{10}(n!)-\lfloor\log_{10}(n!)\rfloor,\,\,n\in\mathbb N,$$
are dense in $[0,1]$.
In particular, we shall prove that for any $c,d$, with $(c,d)\subset [0,1]$, there exist an $n\in\mathbb N$, such that $a_n\in (c,d)$.
This will be achieved in the following way. Will shall try to find $k,\ell\in\mathbb N$, such that the mantissas of
$$
N_j=10^k+j, \quad j=1,\ldots,\ell
$$
are all less that $d-c$, i.e., $\text{m}(N_j)\in (0,d-c)$, and their sum exceeds 1,
i.e., $\sum_{j=1}^\ell \text{m}(N_j)>1$.
Suppose that we have found such $k$ and $\ell$. If $\ell_0<\ell$, such that $\sum_{j=1}^{\ell_0} \text{m}(N_j)\le 1$, while $\sum_{j=1}^{\ell_0+1} \text{m}(N_j)> 1$, then the numbers
$$
b_j=\sum_{i=1}^j\text{m}(N_i)=\text{m}(N_1N_2\cdots N_j), \quad j=1,\ldots,\ell_0,
$$
are distributed in $[0,1)$ is a way that
$$
0<b_1<b_2<\ldots<b_{\ell_0}\le 1<b_{\ell_0+1}
$$
and $b_j-b_{j-1}<d-c$. Hence, at least of the numbers
$$
\text{m}(n!)\in(c,d), \quad \text{for at least one of the numbers}\,\,\,n=N_1,\ldots,N_{\ell_0},
$$
The existence of suitable $k,\ell$ is provided by the following estimate:
$$
\prod_{j=1}^{\lfloor 5\sqrt{10^k}\rfloor} \left(1+\frac{j}{10^k}\right)>\sum_{j=1}^{\lfloor 5\sqrt{10^k}\rfloor}\frac{j}{10^k}\ge
\frac{1}{10^k}\cdot \frac{1}{2}(\lfloor 5\sqrt{10^k}\rfloor)^2>10.
$$
Hence, $k$ nad $\ell$ should be picked so that
$$
\log\left(1+\frac{5}{\sqrt{10^k}}\right)<d-c\quad\text{and}\quad
\ell=\lfloor 5\sqrt{10^k}\rfloor.
$$
\cdotinstead of.and\midinstead of|to give the spacing around the symbols. Please don't mix symbols for quantifiers $\forall$, $\exists$ with words in the same line. – GNUSupporter 8964民主女神 地下教會 Jan 28 '21 at 10:03