$\sqrt{a+b} (\sqrt{3a-b}+\sqrt{3b-a})\leq4\sqrt{ab}$
Presumably we also have the restriction $a,b\ge 0$.
With that assumption we can proceed as follows . . .
If $a+b=0$, then $a=b=0$, and for that case, the inequality clearly holds.
So assume $a+b > 0$.
Since the inequality is homogeneous, the truth of the inequality remains the same if $a,b$ are scaled by an arbitrary positive constant, hence without loss of generality, we can assume $a+b=1$.
Replacing $b$ by $1-a$, it remains to prove $$ \sqrt{4a-1}+\sqrt{3-4a}\le 4\sqrt{a(1-a)} \qquad\qquad\;\, $$ for all $a\in \left[{\large{\frac{1}{4}}},{\large{\frac{3}{4}}}\right]$.
From here it's just routine algebra . . . \begin{align*} & \sqrt{4a-1}+\sqrt{3-4a}\,\le 4\sqrt{a(1-a)}\\[4pt] \iff\;& \left(\sqrt{4a-1}+\sqrt{3-4a}\right)^2\le \left(4\sqrt{a(1-a)}\right)^2\\[4pt] \iff\;& 2+2\sqrt{(4a-1)(3-4a)}\,\le -16a^2+16a\\[4pt] \iff\;& \sqrt{(4a-1)(3-4a)}\,\le -8a^2+8a-1\\[4pt] \iff\;& (4a-1)(3-4a)\le \left(-8a^2+8a-1\right)^2\\[4pt] \iff\;& -16a^2+16a-3\le 64a^4-128a^3+80a^2-16a+1\\[4pt] \iff\;& 64a^4-128a^3+96a^2-32a+4\ge 0\\[4pt] \iff\;& 16a^4-32a^3+24a^2-8a+1\ge 0\\[4pt] \iff\;& (2a-1)^4\ge 0\\[4pt] \end{align*} which is true.
Note:$\;$For the reverse implications, we need to have $-16a^2+16a\ge 0$ and $-8a^2+8a-1\ge 0$, both of which hold since $a\in \left[{\large{\frac{1}{4}}},{\large{\frac{3}{4}}}\right]$.