Before arrival, Comet 67P/Churyumov-Gerasimenko had never been seen close up, so the race to find a suitable landing site for the 200-pound (100 dilograms) lander could only begin when Rosetta rendezvoused with the comet August 6.
The landing is expected to take place in mid-November when the comet is about 279 million miles (450 million kilometers) from the Sun, before activity on the comet reaches levels that might jeopardize the safe and accurate deployment of Philae to the comet’s surface and before surface material is modified by this activity.
The comet is on a 6.5-year orbit around the Sun and today is 324 million miles (522 million km) from it. At their closest approach August 13, 2015, just under a year from now, the comet and Rosetta will be 115 million miles (185 million km) from the Sun, meaning an eightfold increase in the light received from our star.
While Rosetta and its scientific instruments will watch how the comet evolves as heating by the Sun increases, observing how its coma develops and how the surface changes over time, the lander Philae and its instruments will be tasked with making complementary in situ measurements at the comet’s surface. The lander and orbiter also will work together using the CONSERT experiment to send and detect radio waves through the comet’s interior in order to characterize its internal structure.
Choosing the right landing site is a complex process. That site must balance the technical needs of the orbiter and lander during all phases of the separation, descent, and landing, and during operations on the surface with the scientific requirements of the 10 instruments on board Philae.
A key issue is that uncertainties in the navigation of the orbiter close to the comet mean that it is only possible to specify any given landing zone in terms of an ellipse — covering up to 1 square km — within which Philae might land.
For each possible zone, important questions must be asked: Will the lander be able to maintain regular communications with Rosetta? How common are surface hazards such as large boulders, deep crevasses, or steep slopes? Is there sufficient illumination for scientific operations and enough sunlight to recharge the lander’s batteries beyond its initial 64-hour lifetime, while not so much as to cause overheating?
To answer these questions, data acquired by Rosetta from about a 62-mile (100km) distance have been used, including high-resolution images of the surface, measurements of the comet’s surface temperature, and the pressure and density of gas around the nucleus. In addition, measurements of the comet’s orientation with respect to the Sun, its rotation, mass, and surface gravity have been determined. All of these factors influence the technical feasibility of landing at any specific location on the comet.
This weekend, the Landing Site Selection Group, composed of engineers and scientists from Philae’s Science, Operations and Navigation Center at CNES; the Lander Control Center at DLR; scientists representing the Philae Lander instruments; and ESA’s Rosetta team met at CNES, Toulouse, to consider the available data and determine a short list of five candidate sites.
“This is the first time landing sites on a comet have been considered,” said Stephan Ulamec from DLR. “Based on the particular shape and the global topography of Comet 67P/ Churyumov-Gerasimenko, it is probably no surprise that many locations had to be ruled out. The candidate sites that we want to follow up for further analysis are thought to be technically feasible on the basis of a preliminary analysis of flight dynamics and other key issues. For example, they all provide at least six hours of daylight per comet rotation and offer some flat terrain. Of course, every site has the potential for unique scientific discoveries.”
“The comet is very different to anything we’ve seen before and exhibits spectacular features still to be understood,” said Jean-Pierre Bibring, a lead lander scientist and principal investigator of the CIVA instrument. “The five chosen sites offer us the best chance to land and study the composition, internal structure, and activity of the comet with the 10 lander experiments.”
The sites were assigned a letter from an original preselection of 10 possible sites, which does not signify any ranking. Three sites (B, I, and J) are located on the smaller of the two lobes of the comet, and two sites (A and C) are located on the larger lobe.
Summary of the five candidate sites
Site A is an interesting region located on the larger lobe but with a good view of the smaller lobe. The terrain between the two lobes is likely the source of some outgassing. Higher-resolution imaging is needed to study potential surface hazards such as small depressions and slopes, while the illumination conditions also need to be considered further.
Site B, within the crater-like structure on the smaller lobe, has a flat terrain and is thus considered relatively safe for landing, but illumination conditions may pose a problem when considering the longer-term science planning of Philae. Higher-resolution imaging will be needed to assess the boulder hazards in more detail. In addition, the boulders are also thought to represent more recently processed material, and therefore this site may not be as pristine as some of the others.
Site C is located on the larger lobe and hosts a range of surface features including some brighter material, depressions, cliffs, hills and smooth plains, but higher-resolution imaging is needed to assess the risk of some of these features. It also is well illuminated, which would benefit the long-term scientific planning for Philae.
Site I is a relatively flat area on the smaller lobe that may contain some fresh material, but higher-resolution imaging is needed to assess the extent of the rough terrain. The illumination conditions should also allow for longer-term science planning.
Site J is similar to site I, and also on the smaller lobe, offering interesting surface features and good illumination. It offers advantages for the CONSERT experiment compared with Site I, but higher-resolution imaging is needed to determine the details of the terrain, which shows some boulders and terracing.
The next step is a comprehensive analysis of each of the candidate sites to determine possible orbital and operational strategies that could be used for Rosetta to deliver the lander to any of them. At the same time, Rosetta will move to within 30 miles (50km) of the comet, allowing a more detailed study of the proposed landing sites.
By September 14, scientists will assess and rank the five candidate sites, leading to the selection of a primary landing site, for which a fully detailed strategy for the landing operations will be developed, along with a backup.
During this phase, Rosetta will move to within 12–19 miles (20–30km) of the comet, allowing even more detailed maps of the boulder distributions at the primary and backup landing sites to be made. This information could be important in deciding whether to switch from primary to backup.
The Rosetta mission team is working toward a nominal landing date of November 11, but confirmation of the primary landing site and the date will likely only come October 12. This will be followed by a formal Go/No Go from ESA, in agreement with the lander team, after a comprehensive readiness review October 14.
“The process of selecting a landing site is extremely complex and dynamic; as we get closer to the comet, we will see more and more details, which will influence the final decision on where and when we can land,” said Fred Jansen from ESA. “We had to complete our preliminary analysis on candidate sites very quickly after arriving at the comet, and now we have just a few more weeks to determine the primary site. The clock is ticking, and we now have to meet the challenge to pick the best possible landing site.”