The craft's mission would entail going from one geologic site to the next, examining the moon's oceanic surface and atmosphere to see how viable it'd be for human habitation.

"Mass spectrometry would reveal the composition of the surface and the atmosphere," the school writes. "Gamma-ray spectrometry would measure the composition of the shallow subsurface. Meteorology and geophysics sensors would measure atmospheric conditions such as wind, pressure, temperature and other factors, as well as seismic activity. Additionally, a camera suite would characterize the geologic and physical nature of the moon's surface and help find subsequent landing sites."

If you're wondering how the Dragonfly will maintain power throughout its missions, here's a hint: It won't be gathered from the sun. Instead, a Multi-Mission Radioisotope Thermoelectric Generator will keep the craft in the air.

Compared to a land-based craft, the school says that the Dragonfly is much more efficient because it can, well, fly, from one test site to another and give more of a return on investment. Sometime later this fall NASA will make its pick for the winning New Frontiers mission and said mission is expected to launch in the middle of 2019.