Bài 4:

$A+2=1+2+2^2+2^3+...+2^{11}$

$=(1+2)+(2^2+2^3)+....+(2^{10}+2^{11})$

$=(1+2)+2^2(1+2)+....+2^{10}(1+2)$

$=(1+2)(1+2^2+....+2^{10})$

$=3(1+2^2+...+2^{10})\vdots 3$

Vậy $A+2\vdots 3$ nên $A$ không chia hết cho $3$

Bài 5:

$n^2+n+1=n(n+1)+1$
Vì $n,n+1$ là hai số tự nhiên liên tiếp nên sẽ tồn tại một số chẵn và 1 số lẻ

$\Rightarrow n(n+1)$ chẵn 

$\Rightarrow n^2+n+1=n(n+1)+1$ lẻ (điều phải chứng minh) 

Lời giải:

$A=(1+2)+(2^2+2^3)+....+(2^{2020}+2^{2021})$

$=3+2^2(1+2)+....+2^{2020}(1+2)$

$=3+3.2^2+....+3.2^{2020}$

$=3(1+2^2+....+2^{2020})\vdots 3$
Ta có đpcm.

\(A=\left(1+2\right)+2^2\left(1+2\right)+...+2^{10}\left(1+2\right)=3+2^2.3+...+2^{10}.3=3\left(1+2^2+...+2^{10}\right)⋮3\)

\(A=1+2+2^2+2^3+...+2^{10}+2^{11}\)

\(=\left(1+2\right)+2^2\left(1+2\right)+...+2^{10}\left(1+2\right)\)

\(=\left(1+2\right)\left(1+2^2+...+2^{10}\right)\)

\(=3\left(1+2^2+...+2^{10}\right)\) ⋮3

\(A=1+2+2^2+2^3+............+2^{11}\)

\(=\left(1+2\right)+\left(2^2+2^3\right)+...+\left(2^{10}+2^{11}\right)\)

\(=\left(1+2\right)+2^2\left(1+2\right)+...+2^{10}\left(1+2\right)\)

\(=\left(1+2\right)\left(1+2^2+...+2^{10}\right)\)

\(=3\cdot\left(1+2^2+...+2^{10}\right)⋮3\)

=>đpcm

A=\((1+2)+\left(2^2+2^3\right)+...+\left(2^{19}+2^{20}\right)\)

A=\(3.1+2^2\left(1+2\right)+...+2^{19}\left(1+2\right)\)

A=\(3.1+3.2^2+...+3.2^{19}\)

A=\(3\left(1+2^2+...+2^{19}\right)\)\(⋮3\)

Vậy A\(⋮3\)

A=

A=

A=

A=

NÊN  A