Sendov conjecture, Borcea variance conjectures and Schoenberg inequalities

Let $F(z)=\prod\limits_{k=1}^n(z-z_k)$ be a monic complex polynomial of degree $n$. In 1998, Pawlowski [Trans. Amer. Math. Soc. 350 (1998)] studied the radius $\gamma_n$ of the smallest concentric disk with center at $\tfrac{\sum\limits_{k=1}^nz_k}{n}$ contained at least one critical point of $F(z)$. He showed that $\gamma_n\le \tfrac{2n^\frac{1}{n-1}}{n^\frac{2}{n-1}+1}$. In this paper, we refine Pawlowski's result in the spirit of Borcea variance conjectures and classic Schoenberg inequality, specifically, we show that $\gamma_n\le\sqrt{\tfrac{n-2}{n-1}}$ in a very concise manner. Moreover, we obtain various generalizations of Schoenberg inequalities based on classic Schoenberg inequality including refining Lin-Xie-Zhang's result [J. Math. Anal. Appl. 502 (2021)], which is inspired by the author's recent work on Clarkson-McCarthy inequalities [arXiv:2410.21961] . Finally, we make $D$-companion matrix introduced by Cheung-Ng [Linear Algebra Appl. 432 (2010)] and operator inequalities involved Schatten $p$-norm react so that we provide an additional relationship between the zeros of $F(z)$ and its critical points in the case where all $z_k\ge 0$, which can be regarded as complements of Schmeisser's result [Comput. Methods Funct. Theory 3 (2003)]. By an operator 2-norm identity, we also prove Sendov conjecture with a condition that depends only on $\left( \tfrac{1}{n-1}\sum\limits_{k=1}^{n-1}\left|z_k-z_n\right|^2\right)^\frac{1}{2}$.
Comment: 16 pages. All comments are welcome!