let $a^2_{i}=x_{i},1\le i\le n$,then
if $x_{1},x_{2},\cdots,x_{n}<1$, are non-negative real numbers,such
$$\dfrac{x_{1}+x_{2}+\cdots+x_{n}}{n}=r\ge\dfrac{1}{3}$$
then we have
$$\dfrac{\sqrt{x_{1}}}{1-x_{1}}+\dfrac{\sqrt{x_{2}}}{1-x_{2}}+\cdots+\dfrac{\sqrt{x_{n}}}{1-x_{n}}\ge\dfrac{n\sqrt{r}}{1-r}$$
Proof
Apply RCF-Theorem to the function
$$f(u)=\dfrac{\sqrt{u}}{1-u},0\le u\le 1$$
then
$$f'(u)=\dfrac{3u^2+6u-1}{4u\sqrt{u}(1-u)^2}$$
it follows that $f$ is convex on $[\dfrac{2}{\sqrt{3}}-1,1)$,since $s=\dfrac{1}{3}>\dfrac{2}{\sqrt{3}}-1$,the function $f$ is convex on $[s,1)$
By RCF-Theorem,
it suffices to show that $g(x)\le g(y)$ for $0\le x\le s\le y<1$ and $x+(n-1)y=ns$
where
$$g(t)=\dfrac{f(t)-f(s)}{t-s}$$
for convenience,let $$a=\sqrt{x},b=\sqrt{y},c=\sqrt{s}$$
we have
$$g(t^2)=\dfrac{f(t^2)-f(c^2)}{t^2-c^2}=\dfrac{1+ct}{(1-c^2)(1-t^2)(t+c)}$$
and
$$g(x)-g(y)=g(a^2)-g(b^2)=(a^2-b^2)\dfrac{a^2+b^2+c(a+b)+c^2-1+ab(1+c^2)+abc(a+b)}{(1-c^2)(1-a^2)(1-b^2)(a+c)(b+c)}$$
since
\begin{align*}
&a^2+b^2+c(a+b)+c^2-1+ab(1+c^2)+abc(a+b)\\
&\ge a^2+b^2+c(a+b)+c^2-1\\
&\ge a^2+b^2+c\sqrt{a^2+b^2}+c^2-1
\end{align*}
it is enought to show that
$$x+y+\sqrt{s(x+y)}+s-1\ge 0$$
Indeed,we have
$$x+y=\dfrac{ns+(n-2)s}{n-1}\ge\dfrac{ns}{n-1}$$
and therefore
$$x+y+\sqrt{s(x+y)}+s-1\ge\left(\dfrac{n}{n-1}+\sqrt{\dfrac{n}{n-1}+1}\right)s-1\ge 3s-1=0$$
Equality occurs only for $x_{1}=x_{2}=\cdots=x_{n}=r$