On the number of zeros of diagonal cubic forms over finite fields

Abstract: Let ${\mathbb F}q$ be the finite field with $q=p^k$ elements with $p$ being a prime and $k$ be a positive integer. For any $y, z\in\mathbb{F}_q$, let $N_s(z)$ and $T_s(y)$ denote the numbers of zeros of $x_1^{3}+\cdots+x_s^3=z$ and $x_1^3+\cdots+x{s-1}^3+yx_s^3=0$, respectively. Gauss proved that if $q=p, p\equiv1\pmod3$ and $y$ is non-cubic, then $T_3(y)=p^2+\frac{1}{2}(p-1)(-c+9d)$, where $c$ and $d$ are uniquely determined by $4p=c^2+27d^2,~c\equiv 1 \pmod 3$ except for the sign of $d$. In 1978, Chowla, Cowles and Cowles determined the sign of $d$ for the case of $2$ being a non-cubic element of ${\mathbb F}p$. But the sign problem is kept open for the remaining case of $2$ being cubic in ${\mathbb F}_p$. In this paper, we solve this sign problem by determining the sign of $d$ when $2$ is cubic in ${\mathbb F}_p$. Furthermore, we show that the generating functions $\sum{s=1}^{\infty} N_{s}(z) x^{s}$ and $\sum_{s=1}^{\infty} T_{s}(y)x^{s}$ are rational functions for any $z, y\in\mathbb F_q^*:=\mathbb F_q\setminus {0}$ with $y$ being non-cubic over ${\mathbb F}_q$ and also give their explicit expressions. This extends the theorem of Myerson and that of Chowla, Cowles and Cowles.