I'm trying to prove that every topological manifold $M^n$ (with or without boundary) is locally path-connected. My attempt:
(Without boundary): Let $x\in M^n$ and $V$ be any open set containing $x$. Let $(U,\phi)$ be a chart containing $x$, so $U\cap V$ is also open, and $U\cap V$ is homeomorphic to $\phi(U\cap V)\subset\mathbb{R}^n$, which may or may not be path-connected. If it is path-connected, then $U\cap V= \phi^{-1}(\phi(U\cap V)\subset V$ is path connected, since path-connectectedness is preserved under homeomorphism and we are done. If $\phi(U\cap V)$ is not path-connected, then since it is open, we can find a sufficiently small $r$ so $B_r(\phi(x))\subset \phi(U\cap V)$. $B_r(\phi(x))$ is path-connected, so $x\in\phi^{-1}(B_r(\phi(x)))\subset V$ is path-connected.
(With Boundary): Let $\mathbb{H}^n=\{(x^1,...,x^n)\in\mathbb{R}^n:x^n=0\}.$ Replace $\mathbb{R}^n$ with $\mathbb{H}^n$ and $B_r(\phi(x))$ with $\mathbb{H}^n\cap B_r(\phi(x))$ in the argument above.
Does this look right?
Now let’s focus on a smooth manifold $M;$ by definition we now that for any point $p \in M$ exists a neighborhood $U_{p}$ of $p$ and a homeomorphism $\phi\colon U_{p} \to \mathbb{R}^{d}.$
Since $\mathbb{R}^{d}$ (with the Euclidean topology) is locally path connected, $M$ inherits this property through $\phi,$ and we can conclude that a path connected manifold is connected and that if the manifold is locally path connected, then it is path connected if and only if it is connected.