Let's consider a (partial) differential equation with analytic coefficients. The initial conditions may be non-analytic*.
Is it possible a solution $f$, which is non-analytic at any point of the domain?
*Even if the initial conditions are analytic, it is possible that the solution is not [1].
Points off for the rude response to Otis' sincere attempt to help you!
Deanne is correct, but you can see this simply even with the operator $\partial_{x_1}$ in $\mathbb R^n$. If $u(0, x_2, \ldots, x_n)$ is nowhere analytic, then the solution of $\partial u/ \partial_{x_1} = 0$ is constant in $x_1$ but never analytic in the orthogonal directions.
On the other hand, there is a class of operators known as analytic hypoelliptic (which includes both the Laplacian for any analytic metric and the associated heat operator) for which such a statement is true: $L u = f$ and $f$ analytic implies $u$ analytic.
However as the paper you reference indicates, all sorts of wild things can happen in general; that paper gives an example of a constant coefficient system and analytic ``initial data'' where the solution is not analytic. Actually, that is a rather nonstandard sort of initial value problem where Cauchy data for one component is posed on one hypersurface and Cauchy data for the second component is posed on a transverse hypersurface.
Take the Lewy operator $\mathcal L$ in $\mathbb R^3_{x,y,t}$ $$ \mathcal L=\partial_x+i\partial_y+i(x+iy)\partial_t. $$ There exists a set $S$ of second category in $C^\infty(\mathbb R^3)$ such that for all $f\in S$, the equation $\mathcal L u=f$ has no distribution solution. So even with polynomial (even affine here) coefficients, a complex vector field could have terrible pathologies. A good explanation of this phenomenon was given by Lars Hörmander and developed further by several authors. The symbol of the Hans Lewy operator is $a+ib$ and for each point $X\in \mathbb R^3$, you can find $\Xi\in \mathbb R^3$ such that at $(X,\Xi)$, $$ a=b=0\quad\text{and the Poisson bracket {$a,b$} is positive}. $$
This can't happen if the PDE is either elliptic or parabolic. If the PDE is hyperbolic and you start with initial data that is nowhere analytic, then it seems plausible that the resulting solution is also nowhere analytic. But I don't have a rigorous proof of this. The idea would be to assume that there is a point where the solution is analytic in a neighborhood and try to derive a contradiction by propagating the analyticity backwards back to the given intial data.
