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Van Kane

JUICE at Europa

Posted by Van Kane

13-01-2015 14:03 CST

Topics: Jupiter's moons, Europa, Ganymede, Callisto, Europa Clipper, Jupiter, JUICE

Late in 2030, Europe’s Jupiter Icy moon Explorer (JUICE) spacecraft will twice zoom past Europa, a world that has all the ingredients to harbor life. During the minutes of each closest flyby, it will study areas identified from images taken in the 1990s by the Galileo spacecraft as locations of recent geological activity. Then after those two encounters, the spacecraft will move on to study Jupiter and the moons Ganymede and Callisto. Unless another space agency commits to another mission that will visit Europa, this will be our only chance to explore Europa in the next several decades. (But see the note at the end of this post.)

JUICE at Jupiter


JUICE at Jupiter
Artist's concept of the Jupiter Icy Moons Explorer (JUICE) spacecraft at Jupiter.

Large space missions are planned in progressively more detailed stages. The European Space Agency selected the JUICE mission based on a concept study (the so-called ‘Yellow Book’). Last fall, the mission team completed the more detailed Definition Study (the so-called ‘Red Book’) that tells us much more about how the mission will study each of its target worlds.

Adequately describing the exploration planned for the JUICE mission in the Definition Study would be too much for one blog post. Over the coming year, I’ll cover each of JUICE’s major scientific targets. Among the readers of my posts, however, Europa has been a favorite subject, and I’ll kick off this series with the plans to study this moon. (For anyone willing to read a technical document, you can read the full JUICE Red Book here.)

Almost everything we know about Europa comes from the 1990s Galileo spacecraft’s eleven flybys of this moon. While the JUICE spacecraft will perform just two flybys, it is likely to greatly deepen our understanding Europa and may even radically transform it.

The Galileo spacecraft carried instruments that were based on 1970s technology. (Problems with the Space Shuttle program repeatedly delayed its launch, and it arrived at Jupiter in 1995.) The JUICE spacecraft will carry instruments based on today’s technology. Where Galileo and JUICE will have similar instruments, the JUICE instruments will be far more capable. JUICE’s imaging spectrometer, for example, will have approximately an order of magnitude more spectral sensitivity and up to four times better spatial resolution than its Galileo equivalent. JUICE will also carry a number of new instruments that had no equivalent on Galileo, such as an ice penetrating radar that will see structures beneath the surfaces of the three icy moons.


NASA / JPL-Caltech / University of Arizona

Much of Europa's surface shows evidence for recent geologic activity either in the form of surface features such as ridges, chaotic terrain, or reddish material that may be from the ocean below.

JUICE also will return far more data than its predecessor. Galileo’s main antenna failed to deploy, leaving only the low gain antenna to return data. Compared to the data return that was planned, what we received from Galileo was like a getting a shot glass of water instead of a lake. JUICE’s main antenna will not require deployment, and minus a major mission failure, we’ll finally get that lake-full of data along with many measurements the Galileo’s instruments could not make.

One unfortunate fact dominates all planning to study Europa. Jupiter is surrounded by a radiation belt that grows more intense closer to the giant planet. At Europa, the radiation is more than 20 times greater than at the more distant Ganymede. This allows the designers of the JUICE spacecraft to undertake comparatively modest radiation hardening to allow the craft to safely spend months in orbit around Ganymede, but to plan for just two quick dashes past Europa.

(As a side note, the capabilities of the JUICE spacecraft and NASA’s proposed Europa Clipper, which would flyby that moon 45 times, are roughly comparable in terms of scientific payload, data communications rate, and power. However, the estimated cost of the Clipper mission is almost twice that of the JUICE mission, with much of the difference likely explained by the additional radiation hardening needed to enable many Europa flybys.)

With just two flybys, the JUICE mission will study in detail just a portion of Europa’s surface. The mission planners have chosen to focus those flybys on areas where Galileo images revealed recent geologic activity. These are terrains where the icy shell has been broken to create regions of chaotic terrain and/or have produced Europa’s characteristic ridges. These regions also have surface materials that suggest water has been brought to the surface from the underlying ocean.

To achieve the best observing conditions for the instruments, the two flybys will occur within 15 degrees of longitude of the center of the far side of Europa from Jupiter and will bring the spacecraft as close as 400 kilometers above the surface. Of the eight possible regions of interest identified to date, seven lie on Europa’s trailing hemisphere which receives the highest radiation loads. (Because Jupiter’s magnetosphere rotates much faster than Europa travels around Jupiter, the highly charged ions that create the high radiation levels slam into the trailing hemisphere; the leading hemisphere has much lower radiation exposure.) 

JUICE focus areas

From ESA's JUICE Red Book

JUICE focus areas
Examples of focus regions on Europa that the JUICE spacecraft may study. Red blocks are the regional focus regions, while the most detailed observations would occur directly below the path of the spacecraft (shown as the colored arcs).

For the two encounters, the JUICE scientific team has identified three key goals. While the plan is to use almost all of JUICE’s instruments during the encounters, for each objective only one or a few of the instruments are expected to provide the prime measurements, while a few others will provide secondary measurements. 

Goal 1: Determine the composition of the non-ice material on the surface, with a focus on substances that relate to potential habitability of the subsurface ocean. 

Galileo’s images revealed that in many places, Europa’s surface ice was reddish or brown. Scientists believe these are locations where fractures in the icy crust has brought materials from the ocean below to the surface. Once on the surface, radiation will modify these materials into sulfuric acid hydrates and hydrated salts. Further geologic activity may return these modified materials to the ocean below where they may be important ingredients to support any life. 

JUICE’s instruments will observe what materials are present on the surface, including those that could indicate biological origins, and gather data to help to explain the origins of these materials (whether they come directly from the subsurface ocean or have been modified on the surface). 

A suite of remote sensing instruments will study the spectra of these materials to determine their composition, with measurements ranging from the ultraviolet through the visible and into the infrared portions of the spectrum. The spacecraft will also use its in-situ particle instruments to directly measure the composition of surface particles expelled from the surface by radiation sputtering. For this goal, the visible-Infrared imaging spectrometer (MAJIS) will be the prime instrument, with the camera (JANUS), UV spectrometer (UVS), and the particle environment package (PEP), which includes a mass spectrometer, playing supporting roles.

Goal 2: Search for liquid water below the surface. 

For this goal, the ice penetrating radar (RIME) is the star. The radar’s radio waves will be able to penetrate as deep as nine kilometers below the surface. From the returned radio signals, scientists will detect both the subsurface structure of the icy shell as well as detect bodies of water. They hope to detect either the top of the ocean itself (assuming that the icy shell is thin, at least below areas of recent geologic activity) or “lakes” trapped within between layers of ice.

Goal 3: Study the active processes

Europa has only a few craters on its surface, allowing scientists to estimate that geologic processes destroy and recreate the entire surface every 100 million years or so. Evidence for the processes that resurface this moons lies across its surface in massive lines of ridges, locations where the crust has been broken and rearranged like jigsaw puzzle pieces, and areas of lumpy terrain. During the flybys, the camera (JANUS) will take the starring role to image and map these terrains for analysis by geologists looking for clues as to how these processes operate.

JUICE’s instruments also will be able to directly ‘taste’ material form the surface. The JUICE spacecraft’s suite of in-situ instruments (PEP) will sample the materials sputtered into space by this continuous radiation bombardment to allow scientists to better understand how this process remakes the surface material.

While the focus of the Europa encounters will be on the high resolution measurements possible only in the minutes around closest approach of each flyby, the spacecraft’s instruments will also make regional observations Europa’s surface to map its geology and composition in the hours before and after each encounter. In addition, JUICE’s camera and UV spectrometers will be used to examine Europa for months from afar to search for possible plumes of water. While there hasn’t been a confirmation of the reported plumes observed with the Hubble Telescope in 2013, any plumes present may only erupt irregularly or at low intensities. 

The JUICE spacecraft’s modern instruments and working high gain antenna means it will return far more data from Europa than the Galileo spacecraft could. Our understanding of this moon likely will become much richer than it is today.

However, it’s also important to understand the limitations of the JUICE mission for studying Europa. Only two locales will receive high resolution imaging, and they will be within a single region of the moon. The JUICE mission’s scientists will select what they believe will be the two most interesting locations within that region with regional studies as the spacecraft approaches and departs. They will be relying on limited and mostly low resolution Galileo data to select their targets that will then be almost 25 years old. With just two encounters, the JUICE spacecraft may give us a biased understanding of this moon because the two sites may not be representative of the active regions found across this moon.  

The radiation hardening needed to do a full survey of Europa just isn’t possible within this mission’s budget (although I hope that the mission’s planners ultimately decide the spacecraft can tolerate an additional flyby or two). Instead, the JUICE spacecraft will go on to do a full study of Ganymede from orbit around that moon.

If NASA’s Europa Clipper mission is funded and reaches Europa, it will conduct at least 45 flybys that will be distributed across the globe and will study a wider variety of terrain types. The larger number of encounters give a much better chance of sampling all the important terrain types. With this many flybys and the possibility of more during an extended mission, the Clipper can do repeat flybys of specific locations to follow up on important discoveries made during the mission. A large number of globally-distributed flybys also are required to enable certain studies such as the gravity studies of the interior or magnetic induction studies of the ocean to constrain its volume.

The Clipper mission may also carry a high resolution camera to search for safe landing sites for a follow on lander mission. (This camera was included in the last documents I saw, but the mission and its budget have yet to be approved and a high resolution camera adds significant costs.) If the Clipper spacecraft carries this camera, then it has a much better chance of finding a safe and scientifically interesting landing site with forty-five encounters than the JUICE spacecraft will have with two.

With luck, we will have both the JUICE and Clipper missions. JUICE will study Ganymede in detail as Clipper will do with Europa. In that case, the JUICE encounters will add to the Clipper’s encounters and allow the measurements of the two missions to be calibrated. If Clipper doesn’t fly, then we will have two encounters for a regional study of Europa from a highly capable spacecraft and its instrument suite.

Breaking news: I listened in on a presentation by Jim Green, head of NASA’s Planetary Science Division at this week’s Small Bodies Assessment Group. Dr. Green says that NASA hopes that it will be able to use the $100M Congress added to NASA’s budget for a Europa mission to enable a New Start for the Europa Clipper program. This is the term for when a mission goes from the wish list to an approved program. This is the first that I had heard that NASA’s management was looking to commit to a Europa mission. This isn’t a done deal: the President’s Office of Budget and Management (OMB) must also approve a new start, and in the past they have not been. (Congress must also approve a new start, but the substantial funding it has already supplied suggests that it would.) We will see with the release of the Fiscal Year 2016 budget request whether OMB’s stance has changed. IF a new start is given, then the important questions will be the total budget for the mission and when launch is planned (which might be in the mid-2020’s).

JUICE Fact Sheet

Mission timeline

Phase/Key dates

Key events

06/2022 – Launch



Jupiter tour

01/2030 - Jupiter orbit insertion



Transfer to Callisto (11 months)

Europa phase: 2 Europa and 3 Callisto flybys (1 month)

Jupiter High Latitude Phase: 9 Callisto flybys (9 months)

Transfer to Ganymede (11 months)

Ganymede tour

09/2032 – Ganymede orbit insertion


Elliptical and high altitude circular phases (5 months)

Low altitude (500 km) circular orbit (4 months)


06/2033 – End of nominal mission




Remote Sensing Instruments


Galileo equivalent?

Radio Science Experiment



Laser Altimeter



Imaging System



Visible-Infrared Hyperspectral Imaging Spectrometer



Ice Penetrating Radar



Submillimetre Wave Instrument



Ultraviolet Imaging Spectrograph




In-situ Instruments


Galileo equivalent?




Particle Package suite


Partially (JUICE adds a neutral and ion mass spectrometer)

Radio and Plasma Wave Instrument



See other posts from January 2015


Or read more blog entries about: Jupiter's moons, Europa, Ganymede, Callisto, Europa Clipper, Jupiter, JUICE


LocalFluff: 01/14/2015 01:24 CST

If it is so expensive and difficult to orbit europa, then maybe we should just keep going with flyby missions? Six out of seven missions to Jupiter were flyby's (Pioneers, Voyagers, Cassini, New Horizons). Voyager passed by Jupiter only 18 months after launch. Maybe 18 month old instruments are better than 18 years old instruments? Maybe a cheap fast flyby every few years is better than the single Europa mission of the century? And a flyby could fly by two or three things on the way. I think that JUICE is a horrible idea. Even if it is the least bad thing which is politically possible, it is still horrible.

Mewo: 01/14/2015 02:26 CST

Could a probe not be placed at the Jupiter-Europa L2 point, where it would be protected from Jupiter's radiation by the moon itself? Of course, this would mean that it would only be able to study the far hemisphere, but that disadvantage would be offset by being able to stay there for a longer time. That said, I like the idea of moving on to Ganymede because that moon deserves a close look as well.

LocalFluff: 01/14/2015 06:30 CST

Mewo: There is unfortunately no Lagrange point among the moons of Jupiter. It is a phenomenon that exists where there are only two dominating massive objects, like Earth and our Moon. Since Jupiter has more than one sizable moon, there are no quiet places in its gravitational surroundings. And also, the radiation is not coming from Jupiter the planet itself. The radiation is generated by particles which hit the magnetic fields around Jupiter, and Europa is pretty much inside that doughnut-shaped nuclear war. Like the van Allen belts around Earth, below which the ISS heeds. It might be easier to land on and dig into Europa for radiation protection, than to orbit it. Maybe, I don't know.

Enzo: 01/14/2015 03:43 CST

JUICE orbiting Ganymede could help future missions by acting as a repeater for data transmission. This could enable cubesat type of missions to return meaningful amount of data. A low power LASER on a cubesat could allow communication from the cubesat to JUICE. The existing camera or even the startracker might be able to act as receivers on JUICE. Information would then be relayed back to earth by JUICE's high gain antenna. Even with a small fraction of the bandwidth demonstrated by LADEE (620 Mbit/s) would be excellent. Hopefully JUICE can help the exploration of the Jupiter system beyond its original misison.

LocalFluff: 01/14/2015 03:59 CST

Enzo: The problem is that JUICE would arrive in the 2030s. And the next probe after that optimistically in the 2040s. How many decades can it work as a communication relay, with about 4% the insolation as at Earth and with no budget for a nuclear power source, nor for serious radiation shielding And laser is not yet applicable at those distances (although in the far future of the JUICE, who knows) Either JUICE won't happen, or it will become several times more expensive. I hope for the latter. But I'm afraid it'll be a piece of junk which takes a decade to get there and then dies very quickly without having found anything new really. And then a quarter of a century from now we will ask ourselves: "Should we repeat this or do something else?"

Barnacle : 01/14/2015 08:44 CST

Europa can sustain large imapct craters on its surface, and there is not a lot of venting like Enceladus as we all can deduce. The ice shell is generally think, not thin. If it is thin, it will be venting and breaking up/moving part during observations between Voyagers and during Galileo observations. Furthermore, 9 km of radar penetration I just don't think is sufficient to penetrate at most places on Europa. Best way to save money is go in quick and dirty, please just send a lander and land it on the reddish brown area where the ocean brought up material from underneath to the surface through the fractures. Please drill into these reddish areas and sample it with instruments like SAM on Curiosity rover to determine if there are organics present and whether the organics are produced from biological means. If yes, get back there to check the place out properly, as the ocean underneath Europa must be teeming with life, as the reddish brown areas are all over Europa's fractures. And let's not forget, we currently think there's more water on Europa than all of Earth's oceans. That means there's enough places for life to evolve in all that liquid water. No need to muck around again and again flyby from a distance and moeny on multiple missions, please just get our hands dirty and test the reddish stuff out quick and fast and go from there before we are all cosmic dust, we can't wait that long, decades for another flyby on top of more flybys.

Enzo: 01/15/2015 01:38 CST

LocalFluff : I agree that JUICE would not last the next large mission to work as a repeater. However, hopefully, tiny probes could be arranged more quickly or even timed to arrive at the end of the nominal mission. The LASER would transmit information from Europa to Ganymede where JUICE would be orbiting. The Europa Ganymede distance varies but, at its minimum, it is similar to the earth-moon distance. LADEE demonstrated 620 Mbit/s at this distance. Granted. it was with a large telescope as receiver, but, as I said, even 1/1000 of that would be an excellent data transfer. More of a problem is that is unlikely that existing imaging system can be recycled as an effective LASER receiver, unless it is designed with this in mind. Even if LASER is not possible, maybe an ordinary transmitter, given the short distance, can transmit something useful from a cubesat to JUICE.

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