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Moons of Mars

The moons of Mars consist of two small, potato-shaped natural satellites, and Deimos, which orbit the planet at relatively close distances and are believed to be remnants of captured asteroids or debris from the early solar system. Discovered in August 1877 by American astronomer using the U.S. Naval Observatory's 26-inch , these moons were named after the sons of , the Greek god of war (equivalent to the Roman Mars)—Phobos meaning "fear" and Deimos meaning "terror." Phobos, the larger and inner moon, measures approximately 27 by 22 by 18 kilometers (17 by 14 by 11 miles) in diameter and orbits Mars three times per Martian day at an average distance of about 9,377 kilometers (5,827 miles) from the planet's center, making it tidally locked and gradually approaching Mars at a rate of 1.8 meters (6 feet) per century. This inward spiral suggests Phobos may either collide with Mars or disintegrate into a ring system within 30 to 50 million years. Deimos, the smaller and outer moon, is roughly 15 by 12 by 11 kilometers (9 by 7 by 6.8 miles) across and completes an orbit every 30.3 hours at an average distance of 23,460 kilometers (14,580 miles) from Mars' center, appearing as a faint star-like point from the surface. Both moons are heavily cratered, with Phobos featuring the prominent Stickney Crater—spanning about 9.5 kilometers (5.9 miles) wide, nearly half its diameter—and exhibit low albedos due to their dark, carbonaceous chondrite-like compositions. The origins of Phobos and Deimos remain a topic of active research, with leading hypotheses including capture from the asteroid belt or formation from material ejected by a massive impact on Mars, potentially linked to the planet's hemispheric dichotomy. Recent supercomputer simulations propose a "disruptive" model where a passing asteroid is torn apart by Mars' gravity, forming a debris disk from which the moons accrete, explaining their orbital alignments and compositions in ways traditional capture theories struggle to match. Observations from missions like NASA's Viking orbiters, Mars Global Surveyor, and Mars Reconnaissance Orbiter have provided detailed imagery and spectral data, confirming the moons' primitive, asteroid-like surfaces but leaving their exact formation unresolved. Upcoming exploration includes Japan's JAXA-led (MMX) mission, scheduled for launch in 2026 with contributions, which will orbit both moons, land on to collect surface samples, and return them to by 2031 to analyze their composition and test origin hypotheses. This effort builds on prior flybys, such as those by the European Space Agency's , and aims to clarify how Phobos and Deimos inform broader questions about solar system formation and Mars' geological history.

History of Discovery

Early Speculation

Early speculation about potential satellites of Mars arose in the , driven by analogies to the known satellite systems of other planets. In his 1610 work Somnium, astronomer proposed that Mars likely possessed two moons, extrapolating from a presumed pattern in the solar system: no moons for and , one for , two for Mars, and four for (as recently observed by Galileo). This idea stemmed from Kepler's broader cosmological framework, which sought harmonious proportions among planetary features, though no telescopic evidence supported it at the time. Throughout the 17th and 18th centuries, astronomers such as and Cassini, who meticulously observed Mars' surface features and rotation, contributed to a climate of expectation for Martian satellites based on these analogies, even as their own studies focused on other aspects like polar caps and markings. Literary works amplified this speculation; in 1726, Jonathan Swift's satirically described two Martian moons—one orbiting three diameters from the planet and the other five—through the voices of Laputan astronomers, remarkably aligning with later observations despite being unverified conjecture. Similarly, Voltaire's 1752 novella referenced Mars' two moons in a among travelers, likely drawing from Swift and prevailing astronomical logic that inner planets had fewer satellites than outer ones. By the , these ideas persisted among astronomers, influencing search efforts. , who would later confirm the moons' existence, explicitly acknowledged Kepler's analogies as the origin of such predictions in his 1878 report, noting how they had motivated generations to anticipate Martian companions. This theoretical groundwork set the stage for dedicated telescopic searches in the late .

Discovery of Phobos and Deimos

The discovery of Mars' moons, Phobos and Deimos, occurred during the planet's close opposition to Earth in August 1877, when American astronomer Asaph Hall systematically searched for potential satellites using the newly commissioned 26-inch refractor telescope at the United States Naval Observatory in Washington, D.C. This instrument, the largest refracting telescope in the world at the time, provided the necessary resolution to detect faint objects near Mars' bright disk. Hall began his observations on August 10, motivated by prior speculation about Martian satellites, but initial attempts were hampered by cloudy weather and the moons' low albedo, which made them barely distinguishable from the planet's glare. On August 11, 1877, Hall first spotted the outer moon, which he later named Deimos, after one of the sons of , the Greek god of war equivalent to the . He confirmed its existence over subsequent nights despite intermittent clouds, noting its faint, star-like appearance. Six days later, on August 17, Hall detected the inner moon, —named for ' other son, symbolizing "fear" while Deimos represents "terror"—during a brief clear interval after nearly abandoning the search due to frustration and poor conditions; his wife, Angelina, encouraged him to continue one final evening. These observations marked the first confirmed detection of natural satellites orbiting Mars, ending centuries of unverified claims. Hall's initial measurements revealed striking orbital characteristics, particularly for Phobos, whose synodic period he estimated at approximately 7 hours and 39 minutes—unusually short for a , prompting immediate questions about its dynamics relative to Mars' rotation. He published his findings in late , including preliminary ephemerides, which allowed other observatories to verify the moons' positions and solidified their reality amid the era's astronomical excitement. The low reflectivity of both bodies, later quantified but evident from the outset, had concealed them from earlier searches, underscoring Hall's with the advanced .

Modern Observations

The and 2 orbiters, launched in 1975 and arriving at Mars in 1976, provided the first close-up images of and Deimos, revealing their irregular, potato-like shapes and heavily cratered surfaces. These observations, captured during orbital surveys, documented numerous impact craters and confirmed the moons' potato-shaped profiles, marking a significant advancement over earlier telescopic views. Building on these foundational images, the Soviet Phobos 2 mission in conducted a close flyby of , acquiring 37 detailed photographs and spectral data that highlighted its rugged terrain and surface . Despite the spacecraft's loss of shortly after the flyby, the collected spectra offered initial insights into Phobos' , suggesting a composition akin to carbonaceous chondrites. Subsequent NASA missions further refined these views through high-resolution imaging. The , operational in the late 1990s, used its Mars Orbiter Camera to capture detailed images of against the Martian horizon, enhancing understanding of its size and albedo variations. Complementing this, the (MRO), launched in 2005 and active through the present, has produced sharp images via the instrument, prominently featuring ' grooves radiating from Stickney crater—the moon's largest impact feature, spanning about 9 kilometers. These images also revealed landslides within Stickney and linear chains of craters, providing evidence of Phobos' dynamic geological history. The European Space Agency's , in orbit since 2003 and continuing flybys as of 2025, has conducted multiple close approaches to , measuring its volume at approximately 5,670 cubic kilometers and density around 1.85 grams per cubic centimeter, indicating a highly porous structure. Recent 2025 analyses from these flybys, including radio science experiments, have confirmed Phobos' to Mars, with its rotation synchronized to its of about 7.65 hours. For Deimos, Mars Express observations have similarly tracked its fainter surface features during distant passes. Ground-based telescopes equipped with have supplemented spacecraft data with measurements of the moons' albedo and rotational s up to 2024. Observations from the Keck Observatory and (VLT) have yielded near-infrared spectra and resolved surface details, estimating ' Bond at around 0.07 and Deimos' at 0.06, consistent with dark, primitive surfaces. These analyses, spanning opposition periods, have refined orbital parameters and detected subtle photometric variations linked to surface properties.

Physical Characteristics

Size and Shape

Phobos, the larger of Mars's two moons, measures approximately 27.4 × 22.2 × 18.4 along its principal axes, yielding a mean of about 11 . Its mass is estimated at 1.0659 × 10^{16} kg. This irregular, potato-like morphology includes a prominent equatorial ridge known as Kepler Dorsum, which spans much of its and contributes to its elongated appearance. Deimos, the smaller moon, has dimensions of roughly 15 × 12 × 11 km, with a mean radius of about 6 km. Its mass is 1.4752 × 10^{15} kg. While still irregular, Deimos exhibits a smoother and more nearly spherical shape compared to , lacking the pronounced ridges or extreme elongations. Phobos possesses approximately 5.6 times the volume of Deimos, highlighting their significant size disparity; both moons are tidally locked to Mars, with their long axes oriented toward the planet. These physical properties have been refined through a combination of optical imaging from missions like Viking Orbiter, , and , analyzed via stereophotoclinometry to produce high-resolution shape models. Mass determinations rely on radio science data, including ranging and gravitational effects measured during flybys in the , with continued refinements from observations extending to 2025.

Surface Features

The surface of Phobos is dominated by Stickney crater, a massive feature measuring approximately 9 km in and up to 2 km deep, which spans nearly one-sixth of the moon's total surface area. This enormous crater exhibits ray-like patterns and internal structures suggestive of a complex formation event, with its rim showing evidence of slumping and secondary cratering. Phobos also features prominent linear grooves that crisscross much of its surface, typically 100-200 m wide and tens of meters deep, concentrated near Stickney but extending globally. These grooves may have formed from rolling boulders ejected during the Stickney or from tidal stresses induced by Mars' gravity, though their exact origin remains debated. In contrast, Deimos displays a smoother overall appearance with fewer prominent large craters, its surface blanketed by a thick layer of fine that partially fills impact features and reduces their visibility. The moon's two primary named craters, Voltaire and Swift, measure approximately 3 km and 1.3 km in diameter, respectively, and represent the largest identifiable structures amid a landscape of smaller, subdued depressions. Evidence of mass wasting, including possible landslides, is indicated by downslope movement of loose accumulating in topographic lows and crater floors, contributing to Deimos' subdued morphology. Both moons exhibit low crater densities relative to their sizes, which may indicate relatively young surfaces or extensive coverage by dust and regolith that obscures older impacts. Their dark appearances are reflected in low albedos of 0.071 for Phobos and 0.068 for Deimos, consistent with carbon-rich, primitive materials. Interpretations of these features suggest that ejecta from Stickney could have been launched into Mars orbit, potentially contributing to dynamical interactions or material transfer influencing Deimos' position. High-resolution shape models from 2023 resolve grooves, craters, and other surface features down to ~100 m on Phobos and ~50 m on Deimos, highlighting ongoing surface evolution derived from modern orbital observations.

Composition and Density

The density of Phobos has been measured at 1.876 g/³, indicating a highly porous interior consistent with a rubble-pile structure composed of loosely aggregated material. This low suggests significant void , estimated at 25–35% of its volume, without evidence of a dense metallic or substantial internal . spectra in the visible and near-infrared ranges reveal a akin to carbonaceous chondrites, featuring carbon-rich materials and aluminosilicates, as inferred from observations matching desiccated CM chondrites. Deimos exhibits an even lower density of 1.471 g/cm³, similarly pointing to a porous, rubble-pile-like interior with possible captured origins, and no detected metallic . Its spectral properties align closely with those of C-type asteroids, characterized by low albedo and featureless reflectance in the visible to near-infrared, indicative of primitive, carbon-rich carbonaceous material. Near-infrared spectra obtained by the instrument on from 2003 onward have identified subtle absorption features suggestive of phyllosilicates on both moons, implying hydrated minerals within their layers. Gravitational analyses from flybys reveal perturbations in the moons' orbits that imply non-homogeneous internal structures, with denser regions potentially concentrated near the equator of . These low densities overall support scenarios involving captured or fragmented precursors, as the porosity levels exceed those typical of monolithic bodies. Surface imaging from orbiters further informs these inferences by revealing thick blankets consistent with porous, unconsolidated interiors.

Orbital Characteristics

Orbits and Periods

Phobos orbits Mars at a mean distance of 9,376 from the planet's , corresponding to a semi-major axis of this value in its nearly equatorial orbit. Its is 7.65 hours, which is shorter than Mars' sidereal of approximately 24.62 hours, resulting in an inclination of 1.08° relative to Mars' and an of 0.015. This rapid orbit causes Phobos to rise in the west and set in the east twice each Martian day when viewed from the planet's surface. Deimos, in contrast, follows a more distant path with a semi-major axis of 23,460 km, an of 30.3 hours, an inclination of 1.79°, and a very low of 0.0002. Its period exceeds Mars' rotation, so Deimos rises in the east and sets in the west but moves slowly enough across the sky to appear nearly stationary to surface observers over short timescales. These orbital parameters have been refined through observations, including and radio tracking data from the Viking Orbiters in the , which provided early precise measurements of positions and motions, and later from the (MRO) since 2006, which improved accuracy via high-resolution and gravity field analysis. The orbital periods can be derived from Kepler's third law, adapted for a orbiting a central body: the period T relates to the semi-major axis a by the formula T = 2\pi \sqrt{\frac{a^3}{[GM](/page/GM)}}, where G is the ($6.67430 \times 10^{-11} m³ kg⁻¹ s⁻²) and M is Mars' mass ($6.4171 \times 10^{23} kg), so the [GM](/page/GM) \approx 4.283 \times 10^{13} m³ s⁻². To arrive at the solution for , first convert the semi-major axis to meters: a = 9,376 km = $9.376 \times 10^6 m. Compute a^3 = (9.376 \times 10^6)^3 \approx 8.242 \times 10^{20} m³. Then, \frac{a^3}{[GM](/page/GM)} \approx \frac{8.242 \times 10^{20}}{4.283 \times 10^{13}} \approx 1.924 \times 10^7 s². The yields \sqrt{1.924 \times 10^7} \approx 4,386 s. Finally, T \approx 2\pi \times 4,386 \approx 27,560 s, or about 7.66 hours, closely matching the observed value of 7.65 hours after accounting for minor perturbations.

Dynamical Interactions

The dynamical interactions between Mars and its moons are dominated by tidal forces, which drive long-term orbital evolution. , orbiting close to Mars, experiences significant that causes its to inward at a rate of approximately 1.8 meters per century. This gradual spiraling is due to the bulge raised on Mars lagging behind 's position, resulting in a net that transfers from the moon's to Mars's . At this rate, is projected to either collide with Mars or disintegrate into a within 30 to 50 million years, depending on the exact dissipation parameters. In contrast, Deimos, located farther from Mars, undergoes outward orbital migration due to similar tidal interactions, though at a much slower pace that is currently too faint to measure directly. This expansion arises because Deimos orbits beyond Mars's synchronous radius, where tidal torques accelerate the moon away from the planet, enhancing its orbital stability over geological timescales—potentially enduring for billions of years without significant disruption. The two moons do not currently share major mean-motion s, as their s (approximately 7.65 hours for Phobos and 30.3 hours for Deimos) yield a of about 1:4, avoiding commensurable configurations that could amplify perturbations. However, Phobos maintains a stable 1:1 spin-orbit , with its rotation period synchronized to its , ensuring the same hemisphere consistently faces Mars—a configuration enforced by . Advanced dynamical models elucidate these interactions, incorporating the Laplace-Runge-Lenz vector to quantify perturbations on Phobos's nearly , which helps track changes in and under tidal influences. Recent 2024 numerical simulations further demonstrate that tidal dissipation effectively damps Phobos's over its evolutionary history, maintaining its current low value of about 0.015 while reconciling past orbital crossings with Deimos.

Origin Theories

Capture Hypothesis

The capture hypothesis proposes that Phobos and Deimos originated as asteroids from the main that were gravitationally captured by Mars. This idea gained traction through observations of their physical properties resembling primitive asteroids, including spectral analyses showing close matches to D-type asteroids for Phobos and both D-type and C-type for Deimos, characterized by red-sloped spectra and low without prominent hydration features. Supporting evidence includes the moons' irregular, potato-like shapes and heavily cratered surfaces, which mirror those of captured rubble-pile asteroids rather than spheroidal bodies formed . Their low bulk densities, approximately 1.88 g/cm³ for and 1.5 g/cm³ for Deimos, further suggest porous, low-gravity structures consistent with asteroidal origins, as would otherwise round them into spheres. Although their near-equatorial orbits challenge simple capture scenarios, the overall and composition point to an external, non-Martian formation environment. Despite these indicators, the hypothesis faces significant dynamical challenges, particularly the low probability of simultaneously capturing two small bodies into stable, low-eccentricity, low-inclination orbits without one being ejected during the process. Standard two-body capture mechanisms yield highly eccentric and inclined trajectories that would lead to rapid collisions between Phobos and Deimos, given their proximity. Achieving a viable capture rate necessitates three-body interactions, such as perturbations from passing asteroids or influences, to dissipate and facilitate temporary binding within Mars' . Specific models address these issues through dynamics, where entering Mars' sphere of influence at low relative velocities (via approaches) can achieve temporary capture, with subsequent orbital circularization via atmospheric gas or forces during Mars' early history. A 2023 discussion highlights the viability of partial capture scenarios, where an incoming is tidally disrupted, allowing fragments to form the moons while resolving simultaneous capture difficulties. These mechanisms underscore the hypothesis's potential, though ongoing simulations emphasize the need for energy dissipation processes to match observed orbits.

Impact Ejection Hypothesis

The impact ejection hypothesis proposes that and Deimos originated from a circum-Martian generated by a massive collision between Mars and a protoplanet-sized impactor, analogous to the giant impact model for Earth's developed by Alastair G. W. Cameron and colleagues in the . In this scenario, the impact vaporizes and ejects material from Mars' mantle and crust, forming a hot, low-mass around the planet from which the moons subsequently coalesce. This theory gained prominence through detailed modeling in the early 2010s, suggesting the impactor was roughly - to Ceres-sized to produce a disk consistent with the moons' small total mass of about 1.08 × 10^16 kg. Supporting evidence includes spectroscopic observations indicating compositional affinities between the moons and Mars' basaltic crust. Thermal Emission Spectrometer data from suggest a basaltic component in the regolith of , potentially with admixed phyllosilicates, consistent with Martian surface materials. Additionally, the grooves on —linear furrows up to 170 km long and 20 m deep—have been interpreted in some models as secondary impact scars from debris in the post-impact disk, potentially linked to the dynamical environment during Deimos' accretion phase. Despite these strengths, the hypothesis faces challenges related to the moons' low masses and orbital configurations. Hydrodynamic simulations indicate that even a modest giant would generate a with 0.1–1% of Mars' mass, far exceeding the combined mass of and Deimos by orders of magnitude, implying inefficient re-accretion or rapid loss of excess material via or fallback to Mars. Furthermore, the moons' near-equatorial, prograde orbits demand that the impact occurred in Mars' equatorial plane and that satellites formed quickly—within 10^3–10^4 years—to avoid from aerodynamic in any residual nebular gas or disk dissipation. Variants of the hypothesis address these issues by invoking multiple smaller impacts rather than a single cataclysmic event, cumulatively building the over time. Alternatively, the moons could represent the surviving rubble-pile remnants of co-orbital debris that coalesced hierarchically in the inner disk, with outer material preferentially lost. These modifications allow for better alignment with the moons' irregular shapes and low densities ( ~1.88 g/cm³; Deimos ~1.5 g/cm³), distinguishing the model from capture theories based on superficial asteroidal resemblances.

Recent Modeling and Evidence

Recent computational modeling has advanced the understanding of Mars' moons' origins by integrating high-resolution simulations of dynamical processes. In 2024, researchers at utilized simulations to propose a disruptive partial capture model, wherein a single approaching Mars on a parabolic is tidally disrupted, with fragments forming a circumplanetary that accretes into and Deimos. This approach, employing the open-source SWIFT code for and N-body integrations, demonstrates that over half of the disrupted fragments escape Mars' gravity, while the remainder collides and grinds into smaller particles capable of circularizing in orbits matching the moons' current positions. The model requires a parent roughly 40-100 km in diameter—far smaller than the Mars-sized impactor in giant scenarios—efficiently distributing material to explain both moons' equatorial, prograde orbits without invoking extensive migration. This disruptive partial capture framework builds on earlier capture hypotheses by incorporating tidal disruption as a key mechanism, with N-body simulations indicating that tens of percent of the asteroid's mass can be bound around Mars, and more than 1% evolving into the accretion zone for moon formation. Hybrid models combining elements of capture and subsequent impacts further refine these probabilities; for instance, variants of the simulations yield capture success rates of approximately 10-20% for scenarios involving partial disruption, highlighting the viability of rubble-pile structures emerging from collisional grinding. These results align with the moons' low densities and spectral similarities to carbonaceous asteroids, providing a parsimonious explanation for their formation from a single progenitor without requiring Mars' crustal material. Observational evidence from recent spacecraft flybys supports the rubble-pile nature implied by capture models. Data from flybys in 2024-2025, analyzed in a comprehensive review, reveal ' irregular gravity field and surface consistent with 25-35% , indicative of a loosely bound rather than a monolithic body. This high , derived from radio science and imaging, bolsters the partial capture hypothesis by suggesting Phobos assembled from disrupted fragments, with tidal stresses further shaping its structure over time. Refinements to impact ejection theories have also incorporated Mars' heterogeneous crust in recent studies, though they remain secondary to capture models in explaining the moons' compositions. However, these models struggle with the moons' near-equatorial orbits unless post-ejection dynamical is invoked, contrasting with the more direct orbital outcomes of partial capture. A November 2025 study proposes an icy-impactor variant of the ejection hypothesis, where collision with a water-ice rich vaporizes ice to cool the , enabling accretion of primitive, porous moons (Phobos ~1.88 g/cm³; Deimos ~1.5 g/cm³) that match observed low densities and carbonaceous-like spectra without excessive volatile loss.

Exploration Efforts

Remote Observations from Orbiters

The first resolved images of were obtained by NASA's spacecraft during its orbital mission around Mars in 1971, revealing the moon as an irregularly shaped, heavily cratered body approximately 26 km across, with the prominent Stickney crater dominating one side. These images, taken from distances as close as 5,000 km, marked the initial detailed of Mars' moons and provided early constraints on Phobos' size and surface morphology. NASA's Viking 1 and 2 orbiters, arriving at Mars in 1976, significantly advanced observations by capturing high-resolution images of during close approaches in 1978, covering about 80% of its illuminated hemisphere at resolutions down to 30 meters and enabling the construction of preliminary surface maps. For Deimos, Viking imaging yielded accurate measurements of its dimensions, confirming it as a smaller, smoother body roughly 12 km in diameter with fewer prominent craters. These datasets from the Viking Visual Imaging System allowed for the first systematic photometric analysis of the moons' surfaces, highlighting their low reflectivity and irregular shapes. The European Space Agency's , in orbit since 2003, has conducted over 20 close flybys of through 2025, approaching as near as 50 km and utilizing the High Resolution Stereo Camera (HRSC) to image craters and grooves at resolutions up to 2 meters per pixel, thereby refining topographic models of the moon's rugged terrain. Complementing these optical data, the Mars Advanced for Subsurface and Sounding (MARSIS) instrument has probed ' subsurface during select flybys, detecting potential low-density layers consistent with a rubble-pile structure up to several hundred meters deep. observations have also included Deimos in wider surveys, though with fewer dedicated close passes. NASA's Mars Atmosphere and Volatile EvolutioN () mission, operational since 2014, has employed its Imaging Ultraviolet Spectrograph (IUVS) to perform ultraviolet spectroscopy of during close approaches as near as 300 km, revealing surface compositions dominated by dark, carbon-rich materials with weak absorption features indicative of phyllosilicates. These spectral measurements, spanning mid- and far-ultraviolet wavelengths, have helped characterize the moons' interaction with Mars' upper atmosphere, including ion effects on and Deimos surfaces. Collectively, these orbiter missions have refined key physical parameters of the moons, such as ' to approximately 0.071 and Deimos' to about 0.068 through multi-wavelength photometry, underscoring their status as among the darkest objects in the Solar System. rates have been precisely measured, confirming ' synchronous 1:1 spin-orbit resonance with a period of 7 hours 39 minutes and Deimos' similar locking at 30 hours 18 minutes, with small librations detected via landmark tracking. To date, no dedicated missions to the moons have been completed, with all data derived from Mars-centric orbiters.

Proposed Sample Return Missions

The Soviet , launched in 1988, represented an early effort to enable surface interaction with , including sample collection for in-situ analysis rather than return to . failed en route to Mars on September 2, 1988, due to a ground control command error that oriented its solar panels away from the Sun, depleting power. successfully entered Mars orbit on January 29, 1989, and conducted remote observations of and Deimos before contact was lost on March 27, 1989, preventing deployment of its small lander platform, which carried instruments for surface sampling and local chemical analysis. Building on this experience, proposed the in the early 2000s, with development accelerating in the for a 2011 launch. The was designed to with , land using retrorockets, and use a pneumatic sampler to collect approximately 100–200 grams of from depths up to 10 cm before ascending via a solid-fuel motor to return the material to in a capsule. The mission failed shortly after launch on November 8, 2011, when its upper stage malfunctioned, leaving the in where it reentered and burned up in January 2012. The total project cost was estimated at about $64 million. In the 2010s, explored concepts under its for Mars moon exploration, including the Phobos And Deimos & Mars Environment (PADME) proposal submitted around 2014. PADME aimed to orbit Mars and perform close flybys of both moons to characterize their composition and the surrounding environment, with designs incorporating modular elements adaptable for future and sampling capabilities, though it was not selected for and effectively canceled. This built on earlier ideas for low-cost access to the moons, emphasizing the need for precursor data to inform sample return strategies. Japan's space agency, , initiated feasibility studies for a sample return in 2015 as a follow-up to its successful missions, with detailed proposals developed through 2019 focusing on collection via a touchdown sampler on the moon's surface. These pre-2020 concepts targeted returning at least 10 grams of material to resolve origin questions, incorporating landing technologies tested on asteroids, and served as the foundation for later mission approval. Proposed sample return missions to and Deimos face significant technical challenges, including the moons' microgravity environments—Phobos has a surface gravity of about 0.0057 m/s², making stable landing and sample ascent difficult without excessive propellant use—and exposure to intense radiation from solar particles and Mars' , which can degrade and require robust shielding. Cost estimates for compact, Discovery-class missions have typically ranged from $300–500 million, constrained by launch vehicles like and the need for efficient propulsion systems.

Planned Future Missions

The Martian Moons eXploration (MMX) mission, led by the Japan Aerospace Exploration Agency (JAXA), represents the most advanced planned effort to directly explore and sample one of Mars' moons. Scheduled for launch in fiscal year 2026 aboard an H3 rocket from Tanegashima Space Center, the spacecraft will arrive at Mars in fiscal year 2027 for initial orbital observations of both Phobos and Deimos before entering a dedicated Phobos orbit around 2029. The mission includes a touchdown on Phobos to collect approximately 10 grams of surface regolith using a sampling device on the lander, which will also deploy a small rover named IDEFIX for mobile surface investigations. This sample return is targeted for Earth arrival in 2031, enabling detailed laboratory analysis of Phobos' composition. Originally planned for a 2024 launch, MMX faced delays due to developmental challenges with the H3 rocket, including a failed maiden flight in 2023, pushing the timeline to 2026 as confirmed in early 2024 updates. By November 2025, JAXA reported steady progress in spacecraft testing, with no further postponements anticipated, maintaining the overall mission architecture. The primary scientific goals center on resolving the moons' origins through isotopic and mineralogical analysis of returned samples, which could distinguish between capture from the asteroid belt and ejection from a Mars impact event. The (ESA) is contributing a surface science package to MMX's lander, including instruments for in-situ composition analysis during the Phobos touchdown, such as a mass spectrometer to assess volatile content and . This collaboration enhances the mission's ability to characterize ' regolith properties on-site, complementing the rover's Raman spectrometer and cameras for subsurface and terrain mapping. NASA's ESCAPADE (Escape and Plasma Acceleration and Dynamics Explorers) mission, consisting of twin small orbiters named Blue and Gold, launched on November 13, 2025, aboard Blue Origin's New Glenn rocket, with arrival in Mars orbit planned for September 2027. While primarily focused on measuring interactions with Mars' and upper atmosphere, the orbiters' positions in the Martian system will provide contextual data on the environment surrounding and Deimos. Looking ahead, China's Tianwen-3 mission aims for a Mars sample return in the early 2030s, with launches planned around 2028 using rockets to collect and return at least 500 grams of surface material by 2031, potentially informing broader models of Martian moon formation through comparative isotopic studies. is exploring concepts for a dedicated lander post-2030 as part of its evolvable Mars campaign, potentially involving robotic precursors to human exploration, though no firm timeline or approval has been announced as of 2025.