An overlayer of normal metal on a superconducting metal film could enhance the Tc of bilayer film. This phenomenon is known as the inverse proximity effect (IPE). In this work, we investigated the effect of the gold (Au) overlayer on the superconducting tantalum (Ta) film and discussed the electromagnetic transport properties of the Ta/Au bilayer film. First, our work focused on the direct current (DC) sputtering parameter of the Ta film. By adjusting substrate temperature and film thickness, we found that a higher temperature (above 295 ⁰C) and a greater film thickness could enhance the Tc of Ta films to about 3.6 K. From the X-ray diffraction patterns, we could also see that the above conditions facilitated the formation of α-Ta. For the Ta film thinner than 133 nm, we could not observe Tc above 2 K. Next, with the thickness of the Ta film fixed at 800 nm, we added an Au overlayer of 10-100 nm thick to investigate its effects on Ta films. With the increase in the thickness of the Au overlayer, the Tc of the bilayer film first increased and then decreased, exhibiting the sign of IPE. A possible explanation for this nonmonotonic relation is that the Au overlayer first mitigated fluctuations in the Ta film and thus enhanced the Tc. However, the proximity effect dominated and thus reduced the Tc as the Au overlayer continued to increase. Furthermore, we checked the existence of 2-D superconductivity by examining the 2-D Tinkham model, the U ∝ -lnH relationship between the activation energy U and the applied field H, and the occurrence of the Berezinskii-Kosterlitz-Thouless transition. Among the seven Ta/Au bilayer samples, the two samples grown on the new silicon substrates exhibited 2-D superconducting behaviors. This result suggests that the normal-superconducting bilayer thin films could be a potential candidate for research on how fluctuations affect 2-D superconducting behavior.