The simplest possible choice for many-body wavefunctions are
product wavefunctions.
That is
$$
\Psi(x_1, x_2, x_3, \ldots, x_A) \approx \phi_1(x_1) \phi_2(x_2) \phi_3(x_3) \ldots
$$
because we are really only good at thinking about one particle at a time. Such
product wavefunctions, without correlations, are easy to
work with; for example, if the single-particle states \( \phi_i(x) \) are orthonormal, then
the product wavefunctions are easy to orthonormalize.
Similarly, computing matrix elements of operators are relatively easy, because the
integrals factorize.
The price we pay is the lack of correlations, which we must build up by using many, many product
wavefunctions. (Thus we have a trade-off: compact representation of correlations but
difficult integrals versus easy integrals but many states required.)