How can I prove that $2^{\sqrt 7}$ is bigger than $5$?
This is the one of my tries: $5=2^{\log_{\ 2} 5}$. Then I should prove that: ${\sqrt 7} > {\log_2 5}$.
So, can you help me end this proof or suggest another?
Hint: $\sqrt{7}>\frac{5}{2}$.
Note that
$$5\lt2^\sqrt7\iff5^\sqrt7\lt(2^\sqrt7)^\sqrt7=2^7=128$$
But clearly $\sqrt7\lt3$, so $5^\sqrt7\lt5^3=125$.
Added later: Going beyond what the OP requests, here's a proof that $6\lt2^\sqrt7$, in enough detail that everything can be checked, I think, without resorting to a calculator.
Note first that
$$2\lt1+{7\over6}\lt\left(1+{1\over6}\right)^7=\left(7\over6\right)^7\implies 2\cdot6^7\lt7^7$$
and
$$3^5=243\lt256=2^8\implies3^5\cdot3^7\lt2^8\cdot3^7\implies3^{12}\lt2\cdot6^7$$
Putting these together, we have
$$3^{12}\lt7^7$$
From here, using the easy inequality $5/2\lt\sqrt7$ (which can be seen from $5^2=25\lt28=4\cdot7$) and the equality $(\sqrt7+1)(\sqrt7-1)=6$, we have
$$\begin{align} 3^{12}\lt7^7 &\implies3^6\lt7^{7/2}\\ &\implies3^6\lt7^{\sqrt7+1}\\ &\implies3^{(\sqrt7-1)(\sqrt7+1)}\lt7^{\sqrt7+1}\\ &\implies3^{\sqrt7-1}\lt7\\ &\implies3^{\sqrt7+1}\lt9\cdot7=63\lt64=2^6=2^{(\sqrt7-1)(\sqrt7+1)}\\ &\implies3\lt2^{\sqrt7-1}\\ &\implies6\lt2^\sqrt7 \end{align}$$
If there's an appreciably easier proof, I'd be interested to see one; I was a little surprised this one took as many steps as it did.
Added yet later: Here's an appreciably easier proof, using the fact that $7\lt64/9$ implies $\sqrt7\lt8/3$ and the inequality $3^8\lt2^{13}$, which can be verified by noting
$$3^8=81^2\lt90^2=8100\lt8160=8\cdot1020\lt8\cdot1024=2^{13}$$
Putting these together, we have
$$\begin{align} 3^8\lt2^{13} &\implies2^8\cdot3^8\lt2^8\cdot2^{13}\\ &\implies6^8\lt2^{21}\\ &\implies6^{8/3}\lt2^7\\ &\implies6^\sqrt7\lt2^7\\ &\implies6\lt2^\sqrt7 \end{align}$$
This solution is clearly worse, but it just goes to prove if you try enough stuff something will work.
You want to prove $a<b$, so prove $2^{(a^2)}<2^{(b^2)}$.
In this case we want $2^{(\log_2{5})^2}<2^7$
Of course $(\log_2{5})^2<3(\log_25)$ (since $2^3=8>5)$.
So it suffices to prove $(2^{log_2{5}})^3<2^7$. But of course $125<128$
Good start. So you need to prove that the square of the 2-log of 5 is less than 7, or equivalently, that the square of the double of the 2-log of 5 is less than 28.
But the square of the double of the 2-log of 5 is actually the square of the 2-log of 25. The latter is less than 5 (because the 2-log of 32 is 5) so its square is less than 25, a fortiori less than 28.
If you wanna go by without calculator then write$\sqrt{7}=\sqrt{8-1}$ then use binomial theorem for rational powers which i assume you know and then do floor function or GIF function greatest integer function $[x]$ and you are done with your work.