Two results on homogeneous Hessian nilpotent polynomials

Let z=(z₁,…,z_n) and , the Laplace operator. A formal power series P(z) is said to be Hessian Nilpotent (HN) if its Hessian matrix is nilpotent. In recent developments in [M. de Bondt, A. van den Essen, A reduction of the Jacobian conjecture to the symmetric case, Proc. Amer. Math. Soc. 133 (8) (2005) 2201-2205. [MR2138860]; G. Meng, Legendre transform, Hessian conjecture and tree formula, Appl. Math. Lett. 19 (6) (2006) 503-510. [MR2170971]. See also math-ph/0308035; W. Zhao, Hessian nilpotent polynomials and the Jacobian conjecture, Trans. Amer. Math. Soc. 359 (2007) 249-274. [MR2247890]. See also math.CV/0409534], the Jacobian conjecture has been reduced to the following so-called vanishing conjecture (VC) of HN polynomials: for any homogeneous HN polynomialP(z) (of degreed=4), we haveΔ^mP^m+1(z)=0for anym?0. In this paper, we first show that the VC holds for any homogeneous HN polynomial P(z) provided that the projective subvarieties Z_P and Z_σ2 of CPⁿ⁻¹ determined by the principal ideals generated by P(z) and , respectively, intersect only at regular points of Z_P. Consequently, the Jacobian conjecture holds for the symmetric polynomial maps F=z−∇P with P(z) HN if F has no non-zero fixed point w∈Cⁿ with . Secondly, we show that the VC holds for a HN formal power series P(z) if and only if, for any polynomial f(z), Δ^m(f(z)P(z)^m)=0 when m?0.