Dr. Ryan Cloutier: “We’ve seen this pattern: rocky inside, gaseous outside, across hundreds of planetary systems. But now, the discovery of a rocky planet in the outer part of a system forces us to rethink the timing and conditions under which rocky planets can form.”

What can rocky planets orbiting in the outer parts of a solar system teach scientists about planetary formation and evolution? This is what a recent study published in Science hopes to address as a team of scientists have discovered a rocky planet orbiting in the outer reaches of an exoplanetary system. This study has the potential to challenge longstanding hypotheses regarding the solar system architecture, specifically regarding rocky planets orbiting closer to their star and larger gas giants orbiting farther away.

For the study, the researchers analyzed four exoplanets in the LHS 1903 system orbiting a red dwarf star, the latter of which is smaller and cooler than our Sun. Due to the planets orbiting closer to their star than our planets orbiting our Sun, the researchers estimated the orbital periods for the four exoplanets were between 2.2 and 29.3 days. However, the researchers were surprised to discover that while the innermost planet was rocky and the second the third planets were gaseous, the outermost planet was also rocky. As a result, this finding contradicts longstanding notions about solar system architecture, specifically regarding our own solar system that rocky planets orbit closer to the star while outer planets are gaseous.

“Since the Apollo era, we’ve known about the prevalence of lobate scarps throughout the lunar highlands, but this is the first time scientists have documented the widespread prevalence of similar features throughout the lunar mare,” said Dr. Cole Nypaver.

Does our Moon exhibit recent tectonic activity? This is what a recent study published in The Planetary Science Journal hopes to address as a team of scientists investigated the potential for our Moon to have exhibited recent tectonic activity despite its interior not being geologically active. This study has the potential to help scientists better understand the processes responsible for tectonic activity on planetary bodies and what this could mean for the formation and evolution of planets and moons throughout the cosmos.

For the study, the researchers created the first global map of small mare ridges (SMRs) on the Moon, which are small, narrow tectonic ridges located within the lava plains on the Moon and are similar to lobate scarps, another frequently observed geologic formation on the Moon. They have been hypothesized to result from the Moon shrinking as it’s cooled over billions of years, with the top crust bucking under the pressure of compression.

Using a combination of lunar global mosaics and images from the Lunar Reconnaissance Orbiter Camera (LROC) Narrow Angle Cameras (NACs), the researchers successfully identified and mapped more than 1,100 new SMRs across the nearside of the Moon. Through this, the researchers demonstrated these SMRs are geologically young compared to the surrounding regions and are widely distributed among the lunar volcanic plains.