Let $S_n$ mean the sum of the first $n$ terms of a series. Because our example has 6 terms,
$S_6=1+3+9+27+81+243$

After you multiplied the series by $3$, it became
$3S_6=3+9+27+81+243+729$

Consider subtracting these two equations:
$$
\begin{array}{rc}
3S_6=&&&\color{red}{3}&+&9&+&27&+&81&+&243&+&729\\
S_6=&1&+&\color{red}{3}&+&9&+&27&+&81&+&243\\
\hline
2S_6=
\end{array}
$$

$$
\begin{array}{rc}
3S_6=&&&3&+&\color{red}{9}&+&27&+&81&+&243&+&729\\
S_6=&1&+&3&+&\color{red}{9}&+&27&+&81&+&243\\
\hline
2S_6=&&&0
\end{array}
$$

$$
\begin{array}{rc}
3S_6=&&&3&+&9&+&\color{red}{27}&+&81&+&243&+&729\\
S_6=&1&+&3&+&9&+&\color{red}{27}&+&81&+&243\\
\hline
2S_6=&&&0&+&0
\end{array}
$$

$$
\begin{array}{rc}
3S_6=&&&3&+&9&+&27&+&81&+&243&+&\color{red}{729}\\
S_6=&\color{red}{1}&+&3&+&9&+&27&+&81&+&243\\
\hline
2S_6=&&&0&+&0&+&0&+&0&+&0
\end{array}
$$

$$
\begin{array}{rc}
3S_6=&&&3&+&9&+&27&+&81&+&243&+&729\\
S_6=&1&+&3&+&9&+&27&+&81&+&243\\
\hline
\color{red}{2S_6=}&\color{red}{728}&+&0&+&0&+&0&+&0&+&0
\end{array}
$$

Sum of a Finite Geometric Series

Let’s find the sum of a general geometric series.
$$
\begin{array}{rc}
S_n=&u_1&+&u_1r&+&u_1r^2&+&…&+&u_1r^{n-2}&+&u_1r^{n-1}
\end{array}
$$

If we multiply this series $S_n$ by $r$, we get
$$
\begin{array}{rc}
rS_n=r(u_1&+&u_1r&+&u_1r^2&+&…&+&u_1r^{n-2}&+&u_1r^{n-1})
\end{array}
$$

If we subtract $S_n$ from $rS_n$, we get
$$
\begin{array}{rc}
\color{red}{rS_n}=&&+&u_1r&+&u_1r^2&+&…&+&u_1r^{n-1}&+&u_1r^n\\
\color{red}{S_n}=&u_1&+&u_1r&+&u_1r^2&+&…&+&u_1r^{n-1}&\\
\hline
\fbox{$\color{red}{rS_n}-\color{red}{S_n}$}=\\
\end{array}
$$

$$
\begin{array}{rc}
rS_n=&&+&u_1r&+&u_1r^2&+&…&+&u_1r^{n-1}&+&\color{red}{u_1r^n}\\
S_n=&\color{red}{u_1}&+&u_1r&+&u_1r^2&+&…&+&u_1r^{n-1}&\\
\hline
(r-1)S_n=&\fbox{$\color{red}{u_1r^n}-\color{red}{u_1}$}&+&0&+&0&+&…&+&0\\
\end{array}
$$

$$
\begin{array}{rc}
rS_n=&&+&u_1r&+&u_1r^2&+&…&+&u_1r^{n-1}&+&u_1r^n\\
S_n=&u_1&+&u_1r&+&u_1r^2&+&…&+&u_1r^{n-1}&\\
\hline
(r-1)S_n=&u_1(r^n-1)\\
\end{array}
$$