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8 Flora

8 Flora is a large, bright main-belt classified as S-type, with a mean diameter of 147 km and a of 0.226, making it one of the innermost substantial asteroids in the Solar System. Discovered on October 18, 1847, by English astronomer John Russell Hind at George Bishop's Observatory in , , it was the eighth identified and named after the of flowers and . Orbiting at a semi-major axis of 2.201 with an eccentricity of 0.156 and inclination of 5.89° relative to the , Flora completes one revolution every 3.27 years, with its closest approach to averaging 0.87 . As the namesake and largest member of the Flora family—a prominent dynamical group in the inner main belt—8 is thought to be the remnant core of a once-larger parent body fragmented by collisions billions of years ago, potentially contributing to the delivery of meteorites to . Its surface composition, dominated by silicates and possibly olivine-rich materials indicative of , shows rotational variations that suggest a heterogeneous interior, with a sidereal period of 12.865 hours. Observations indicate a moderate albedo of about 0.16, consistent with a regolith-covered, stony surface lacking significant metal content. With an of 6.61, Flora reaches apparent magnitudes as bright as 7.9 at opposition, allowing it to be observed with amateur telescopes under good conditions.

Discovery and naming

Discovery

8 Flora was discovered on October 18, 1847, by English astronomer John Russell Hind while observing from George Bishop's private observatory in , . This marked Hind's second asteroid find, following his discovery of on August 13 of the same year, during a period of intensified searches for minor planets in the main after the identification of several new objects in the preceding decade. Initial telescopic observations confirmed 8 Flora as a distinct solar system body through its apparent motion against the fixed background of over successive nights, distinguishing it from known and . The object received the provisional designation (8) upon verification by multiple observatories, reflecting its status as the eighth confirmed . To facilitate further tracking, promptly computed a preliminary and , enabling predictions of the object's position for ongoing observations and orbit refinement by the astronomical community. The name Flora was suggested by shortly thereafter.

Naming

8 Flora is named after the Roman goddess of flowers and spring, a designation proposed by astronomer shortly after its discovery. This choice followed Herschel's 1847 advocacy for a systematic approach to naming celestial bodies using figures from , aiming to provide consistency and avoid nationalistic or arbitrary labels. The official name was confirmed in late 1847, aligning with the convention established for earlier asteroids like and . Unlike some contemporaneous asteroids named after characters from Virgil's —such as 37 —or direct Greek mythological figures, Flora draws specifically from lore, distinct from its Greek counterpart (who inspired the later asteroid 410 ). This emphasis reflects the era's preference for Latin in astronomical designations. The asteroid's astronomical , a stylized flower or rose, was introduced in the mid-19th century, with an early form documented in 1852..svg) It was formally encoded in 17.0 in 2024 (proposed in 2023) as U+1CEC2 𜻂, facilitating its use in digital astronomical contexts.

Orbital characteristics

Orbit

8 Flora follows an elliptical in the inner region of the main , characterized by a semi-major axis of 2.20 . The has an of 0.156, an inclination of 5.89° with respect to the plane, and a sidereal of 3.27 years. These elements are based on observations compiled in the JPL Small-Body Database, with the most recent update incorporating data through September 2025. The perihelion distance measures approximately 1.86 AU, while the aphelion reaches 2.55 AU, placing the asteroid's path well within the stability zone of the inner belt but subject to moderate gravitational perturbations from nearby resonances. The (MOID) with Earth is 0.874 AU, indicating no immediate collision risk; however, close approaches can bring it as near as 0.88 AU, as observed during its opposition in November 2020 when it achieved a of magnitude 8.1. Dynamically, 8 Flora's semi-major axis positions it just beyond the 4:1 mean-motion with —corresponding to the innermost at approximately 2.06 —allowing it to avoid the orbital clearing effects that deplete populations in such resonant zones. This placement contributes to the long-term stability of its trajectory within the broader context of the Flora family, bounded inwardly by the ν₆ secular and outwardly by the 3:1 .

Classification and family

8 Flora is classified as an based on its spectral characteristics, which indicate a composition dominated by silicates such as and . It serves as the primary remnant and parent body of the Flora asteroid family, one of the largest and most prominent families in the inner main asteroid belt; 8 Flora, which constitutes approximately 80% of the family's total mass, with the remaining mass distributed among thousands of smaller fragments greater than 1 km in diameter. The family originated from a catastrophic collisional disruption of the parent body roughly 1 billion years ago, as inferred from the size-dependent spreading of members' orbits due to the Yarkovsky effect. Members of the Flora family exhibit similar proper , clustering around a semi-major axis of approximately 2.2 with low eccentricities (mean ~0.14) and inclinations, reflecting their common dynamical origin and minimal initial dispersion from the breakup event. This dynamical grouping has significant implications for solar system evolution, as the family's proximity to the ν₆ secular facilitates the ejection of fragments into near-Earth orbits over time. The Flora family is compositionally linked to LL-type ordinary chondrites, which represent about 8% of all falls but contribute substantially to Earth-impacting flux through resonant pathways; its location in the inner belt avoids direct placement within major Kirkwood gaps like the 3:1 resonance, preserving family integrity while enabling efficient delivery.

Physical characteristics

Dimensions and mass

The effective of 8 Flora is approximately 146 km, as determined from thermal measurements. Triaxial dimensions are approximately 154 × 148 × 127 km, with a polar (c/a ratio) of 0.82 ± 0.05, based on modeling from imaging and lightcurve inversion techniques. More recent high-angular-resolution observations with the VLT/ instrument have refined these dimensions, confirming the overall scale while highlighting a nearly spherical consistent with re-accumulation after a catastrophic collision. Mass estimates for 8 Flora vary due to challenges in dynamical perturbations from close encounters, ranging from 4.0 × 10¹⁸ to 6.62 × 10¹⁸ , or equivalently (3.33 ± 0.42) × 10⁻¹² M⊙. These values derive from asteroid-asteroid gravitational interactions and planetary ephemerides fitting. Combining these masses with the volume from shape models yields bulk densities of 3.3 ± 0.7 g/cm³, typical for S-type asteroids with low . Infrared surveys such as and AKARI contributed initial size constraints that informed these density calculations.

Composition and surface

8 Flora exhibits an S-type , characterized by moderate and absorption features indicative of a silicate-rich surface composition dominated by and , along with significant nickel-iron metal content. Detailed reveals an olivine-to-pyroxene ratio of approximately 2.8 and abundant coarse-grained metallic phases comprising about 50% of the surface material, consistent with a differentiated yet disrupted parent body. The is measured at around 0.24–0.25, reflecting the bright, stony nature typical of S-class asteroids in the inner main belt. The surface of 8 Flora is expected to consist of a layer formed through repeated impacts, featuring numerous craters of varying sizes but lacking resolved large-scale geological structures such as grooves or ridges due to the absence of high-resolution imaging. As a large without direct encounters, its is inferred from spectroscopic data and dynamical models, suggesting a heavily cratered terrain similar to other S-type bodies like . The collisional history of 8 Flora is tied to the formation of the Flora family approximately 1 billion years ago, implying a major disruptive event that scattered fragments and exposed deeper interior materials to the surface. Its mineralogical signature closely matches that of ordinary chondrites, particularly L-type s, supporting the hypothesis that 8 Flora or its parent body contributed to this meteorite class. Over time, space weathering processes, including micrometeorite bombardment and implantation, likely darken the surface and redden its spectrum, progressively altering the original reflectance properties.

Rotation

8 Flora exhibits a sidereal rotation period of 12.865 hours, as determined from extensive lightcurve data compiled in the Asteroid Lightcurve Database (LCDB). The asteroid's spin is oriented at a high obliquity of approximately 85° relative to its , which causes significant variation in the apparent position of its pole during different observational geometries. Photometric lightcurve analyses typically show a small of about 0.08 magnitudes, consistent with a mildly elongated ; there is no for non-principal (tumbling) rotation or the presence of satellites. This rotation period was confirmed through dedicated photometric campaigns in the , including multi-opposition observations in the that resolved earlier ambiguities in the spin properties.

Observations and studies

Historical observations

Following its on 18 1847, 8 Flora was immediately subjected to intensive astrometric observations from multiple observatories to establish its preliminary orbit, with initial elements computed shortly thereafter based on data spanning late 1847 and early 1848. Throughout the , additional sightings from observatories worldwide, including photographic and visual measurements, progressively refined these orbital parameters; for instance, corrections to earlier ephemerides were published in by analyzing accumulated positions up to that time. These efforts established Flora's eccentric orbit within the inner main , with a semi-major axis of approximately 2.2 AU. Flora's notable brightness was recognized early on, as it appeared as one of the most luminous asteroids visible from Earth, achieving a mean opposition magnitude of +8.7 and ranking as the seventh-brightest overall due to its absolute magnitude of 6.61 and high albedo. This visibility facilitated frequent tracking during oppositions, contributing to improved ephemerides by the late 19th century. A significant observational error occurred on 25 March 1917, when 8 Flora, near opposition, was misidentified as the faint 15th-magnitude variable star TU Leonis, resulting in the latter's incorrect classification as a U Geminorum-type cataclysmic variable based on perceived variability. This misclassification persisted for decades until 1995, when precise orbital computations matched the positions, confirming the identity and annulling the variable star designation. The first photoelectric photometry of 8 Flora was conducted in 1953 by I. I. Ahmad at , yielding lightcurves that showed no detectable rotational variation, consistent with a nearly spherical shape. Subsequent mid-20th-century observations built on this, focusing on positional accuracy rather than photometry. In the 1970s, early spectroscopic studies classified 8 Flora as an , revealing a prominent absorption feature near 1 μm indicative of siliceous composition, with its spectrum displaying the deepest such band among asteroids observed at the time except for . These findings, based on reflectance measurements from 0.3 to 1.1 μm, aligned it with meteorites and confirmed its status within the S-class framework emerging from that era's taxonomic efforts.

Modern observations

Modern observations of 8 Flora, commencing in the late 20th century, have employed , stellar occultations, imaging, and photometry to constrain its shape, size, and surface properties without relying on dedicated spacecraft missions. detections provided early insights into 8 Flora's physical characteristics. In 1982, the successfully detected echoes from 8 Flora, yielding a of approximately 0.16 and an estimated of around 150 km, indicative of a regolith-covered surface similar to other S-type asteroids. Stellar occultations have offered direct silhouette measurements. On October 25, 2013, 8 Flora occulted a background star, with four positive chords recorded by observers across , including sites in , , and Kaikoura; these data refined shape models by fitting ellipse projections and aligning with DAMIT 3D reconstructions. Additional multi-station occultations on October 29, 2004 (observed from sites such as Caballo and Las Cruces) and November 30, 2010 (incorporating Keck II data from Maunakea) further constrained the asteroid's profile, supporting ADAM shape modeling that yielded a diameter of 140 ± 4 . High-resolution visible-light imaging has revealed fine-scale morphology. As part of an ESO Large Programme (199.C-0074), the VLT//ZIMPOL instrument at the acquired disk-resolved images of 8 Flora between May 2017 and September 2019, deconvolved to highlight a nearly spherical shape with minor deviations, consistent with reaccumulation following a disruptive collision; these data refined the volume-equivalent to 146 ± 2 and identified subtle surface irregularities. Complementary observations from other facilities, such as Keck, have corroborated these findings by improving rotational coverage and shape inversion accuracy. Infrared surveys have enabled thermal modeling independent of visible albedo biases. The NEOWISE mission, reactivated from the , observed 8 Flora during its 2010 cryogenic phase, deriving a of 147.49 ± 1.03 and a W1-band of 0.38 ± 0.04 through simultaneous fits to thermal emission and reflected sunlight; these results highlight 8 Flora's high reflectivity typical of S-complex bodies. No dedicated flyby or rendezvous missions have targeted 8 Flora, though it features prominently in wide-field surveys like NEOWISE for contextual studies of the inner main belt. Continuous astrometric monitoring supports orbital refinements. The Jet Propulsion Laboratory's Small-Body Database incorporates over 3,500 observations of 8 Flora, with updates through 2025 (3564 observations as of August 2025) enhancing accuracy via recent ground-based imaging and data. At favorable oppositions near perihelion, 8 Flora achieves a peak of +7.9, rendering it accessible to amateur telescopes, with an of H = 6.61 establishing its scale among main-belt asteroids.

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