Consider the following polynomial: $p(x)=x^{3}-(k-1)x^{2}-(2k-1)x+(k-1)^{2}$, where $k \geq 5$ is a fixed parameter. I am trying to find a strong lower bound on the largest root $x_{\max}$ of the polynomial of the form $x_{\max} \geq f(k)$.
So far I was able to show that $x_{\max} \geq k$ which is quite close to the actual value of the root but I need some help going the extra mile.
I would write this as a comment, but as I'm new here, it doesn't allow me to do so.
Anyway, one can make your bound better by replacing $x_{max}\ge k$ by $x_{max}\ge k+\frac{1}{2k}$. This can be seen by considering $q(y)=p(y+k)=y^3+(2k+1)y^2+(k^2+1)y-k+1=0$. Definitely $q(\frac{1}{k})>0$ and actually, it's not difficult to see $q(\frac{1}{2k})<0$ for $k>3$.
I guess you can keep doing this by adding negative degrees of $k$ to your expression and make your bound better and better. Hope this will help you.
With a little help from Maple, one can derive that asymptotically (in $k$) the largest root satisfies
$$ k + \frac{1}{k} - \frac{1}{k^2} - \frac{3}{k^3} + \frac{4}{k^4} + \frac{14}{k^5} +O(\frac{1}{k^6}) $$
