So let $X$ be a projective hypersurface inside $\mathbb{P}_{\mathbb{Z}}^n$ of degree $d$. 
Assume that

(a) $X(\mathbb{C})$ and $X(\overline{\mathbb{F}}_p)$ are irreducible,

(b) and that $X(\mathbb{C})$ and $X(\overline{\mathbb{F}}_p)$ are smooth varieties (therefore of Zariski dimension $n-1$).

Then we know from the classical Weil conjectures 
and (Hard Lefschetz) that
`
$$
Z(X/\mathbb{F}_p,T)=\frac{P_{n-1}(T)^{(-1)^n}}{(1-T)(1-pT)\cdots (1-p^{n-1}T)},
$$
`
where
$$
P_{n-1}(T)=\prod_{j=1}^{b_{n-1}}(1-\alpha_{j} T),
$$
with $|\alpha_{j}|=p^{(n-1)/2}$ where the $(n-1)$-th Betti number of $X(\mathbb{C})$ is given explicitly by
`
$$
b_{n-1}=\frac{(d-1)^{n+1}+(-1)^{n+1}(d-1)}{d}.
$$
`
The last formula being a direct consequence of Gauss-Bonnet.

Q: So for a general connected projective hypersurface $X$ of $\mathbb{P}_{\mathbb{Z}}^n$ such that

(i) $\dim_{\overline{\mathbb{F}}_p}(X(\overline{\mathbb{F}}_p))=\dim_{\mathbb{C}}(X(\mathbb{C}))=n-1$,

**which is no more assumed to be smooth**, what is the "shape" of $Z(X/\mathbb{F}_p,T)$?

I guess that a precise answer to this question should involve a description of the 
singular locus of $X(\overline{\mathbb{F}}_p)$ and $X(\mathbb{C})$ (the number of components of the singular locus and
the type of singularity for each intersection of two components).

P.S. Note that if one has a precise recipe for the zeta function of such a hypersurface, then by the inclusion-exclusion principle one gets a description of the zeta function of a general (equi-dimensional) projective scheme $X$ of finite type of $Spec(\mathbb{Z})$.