Suspended superconducting nanostructures of MoRe $50%/50%$ by weight are fabricated employing commonly used fabrication steps in micro- and nano-meter scale devices followed by wet-etching with Hydro-fluoric acid of a SiO$_2$ sacrificial layer. Suspe
nded superconducting channels as narrow as $50,rm{nm}$ and length $3,rm{mu m}$ have a critical temperature of $approx 6.5,rm{K}$, which can increase by $0.5rm{K}$ upon annealing at $400,^{circ}mathrm{C}$. A detailed study of the dependence of the superconducting critical current and critical temperature upon annealing and in devices with different channel width reveals that desorption of contaminants is responsible for the improved superconducting properties. These findings pave the way for the development of superconducting electromechanical devices using standard fabrication techniques.
