16 Psyche

Template:Short description Template:For Template:Use dmy dates {{#invoke:infobox|infoboxTemplate | class = vcard | titleclass = fn org | title = 16 Psyche | image = {{#invoke:InfoboxImage|InfoboxImage|image=Psyche VLT.png|upright={{#if:||1.1}}|alt=}} | caption = 16 Psyche imaged by the Very Large Telescope's adaptive optics system in August 2019 | headerstyle = {{#if:#D6D6D6|background-color:#D6D6D6|background-color:#E0CCFF}} | labelstyle = max-width:{{#if:||11em}}; | autoheaders = y

| header1 = Discovery

| header10 = {{#if:|Designations|Designations}}

| header20 = Orbital characteristics{{#ifeq:|yes| (barycentric)}}<ref name=JPL/>

| data21 = | data22 = {{#if:13 September 2023
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| header60 = Proper orbital elements

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| header70 = Template:Anchor{{#if:| Physical characteristics|Physical characteristics}}

| label71 = Dimensions | data71 = Template:Nowrap<ref name=Ferrais-Vernazza-etal-2020/>
Template:Val<ref name=Ferrais-Vernazza-etal-2020/>Template:Efn
Template:Nobr<ref name=Shepard-Richardson-etal-2017/>
Template:Nobr<ref name=Shepard2021/> | label72 = Template:Longitem | data72 = Template:Val<ref name=Vernazza2021/>
Template:Val<ref name=Ferrais-Vernazza-etal-2020/>
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Template:Val Template:Small<ref name=Shepard2021/> | label94 = Temperature | data94 =

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Surface temp.	min	mean	max
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| header110 = Atmosphere

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16 Psyche (Template:IPAc-en Template:Respell) is a large M-type asteroid, which was discovered by the Italian astronomer Annibale de Gasparis, on 17 March 1852 and named after the Greek goddess Psyche.<ref name=Schmadel-2012-dict-mp/>

The prefix "16" signifies that it was the sixteenth minor planet in order of discovery. It is the largest and most massive of the M-type asteroids, and one of the dozen most massive asteroids. It has a mean diameter of approximately Template:Convert and contains about one percent of the cumulative mass of the whole asteroid belt. It was thought to be the exposed core of a protoplanet,<ref name=Bell_AsteroidsII/> but recent observations cast doubt on that hypothesis.<ref name=Elkins-Tanton_2020/><ref name=Shepard2021/>

Psyche will be explored by NASA, with a spacecraft of the same name, marking the first time a manmade object will journey to a metallic asteroid, launched on 13 October 2023,<ref name =Lockhart-2023-09-28/> with an expected arrival in 2029.<ref name=jpl-20221028>Template:Cite press release</ref>

SymbolEdit

File:Psyche insignia.svg

Insignia of the NASA Psyche mission

Astronomers created icon-like symbols for the first fifteen asteroids to be discovered, as a type of shorthand notation consistent with older notation for the classical planets. Psyche was given an iconic symbol, as were a few other asteroids discovered after 16 Psyche. The symbol was a butterfly's wing topped by a star (16 Psyche or 16 Psyche), as the butterfly was a Greek symbol of the soul (psyche being the Greek word for both "butterfly" and "soul").<ref name=Sonntag-1852/> This symbol may have influenced the design of the official insignia for the NASA Psyche mission to this asteroid. It is in the pipeline for Unicode 17.0 as U+1CEC9 𜻉 (File:Psyche symbol (fixed width).svg).<ref name=astunicode>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref name=pipeline>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

However, the iconic symbols for all asteroids were superseded before Psyche's symbol ever came into use. With more than a dozen asteroids discovered, remembering all their individual emblems became increasingly cumbersome, and, in 1851, German astronomer J.F. Encke suggested using a circled number instead: Template:Big. The first asteroid designated with the new scheme was Template:Nobr, when American astronomer J. Ferguson published his observations in 1852.<ref name=Hinton-2001-09-17-USNO/>

CharacteristicsEdit

SizeEdit

The first size estimate of Psyche was Template:Convert and came from IRAS thermal infrared emission observations.<ref name=JPL/> This is 15% larger than the currently accepted mean value, but was later found to be an accurate estimate for the IRAS viewing aspect because Psyche was viewed pole-on at the time of the measurement.<ref name=Shepard-Richardson-etal-2017/><ref name=Lupishko-1999/>

Psyche has been observed to occult a star on nine occasions.<ref name="Shepard-Richardson-etal-2017" /> Four of these, 2004,<ref name="Shepard-Richardson-etal-2017" /> 2010,<ref name="PSI-asteroid-data-sets" /><ref name="Psyche_occultation_2010" /> 2014,<ref name="PSI-asteroid-data-sets" /> and 2019,<ref name="Psyche_occultation_2019" /> generated multi-chord data sets<ref name=PSI-asteroid-data-sets/> and have been used along with adaptive optics imaging and three-dimensional modeling to estimate Psyche's mean diameter, with recent models all converging to an equivalent-volume mean diameter of Template:Val km.<ref name="Hanuš-Viikinksk-etal-2017"/><ref name=DAMIT-1806-cuni-cz/><ref name="Viikinksk-Vernza-etal-2018" /><ref name="Ferrais-Vernazza-etal-2020" /><ref name="Shepard2021" />

File:Psyche asteroid eso.jpg

Multiple views of 16 Psyche imaged by the Very Large Telescope

Mass and bulk densityEdit

Psyche is massive enough that its gravity observably perturbs other asteroids' orbits, which can be used to calculate a mass estimate. Historical values for Psyche's mass have ranged from Template:Val to Template:Val.<ref name=Kuzmanoski_Kovacevic_2002/><ref name=Elkins-Tanton_2020/> However, most recent estimates have begun to converge on values near Template:Val.<ref name=Elkins-Tanton_2020/><ref name=Siltala_Granvik/> Assuming the mean volume of Template:Val, this equates to a bulk density of Template:Val, which is considerably higher than most small Solar System bodies.<ref name=Vernazza2021/><ref name=Elkins-Tanton_2020/><ref name=Siltala_Granvik/>

Shape and spin poleEdit

The first published three-dimensional shape model for Psyche was derived from an analysis of numerous light curves.<ref name="Kaasalainen-etal-2002" /> Since then, additional refinements to the shape have been made based on the inversion of lightcurves, adaptive optics observations, radar observations, thermal imaging, and occultations.<ref name="Hanuš-Viikinksk-etal-2017" /><ref name="Shepard-Richardson-etal-2017" /><ref name = Drummond_etal_2018/><ref name="Viikinksk-Vernza-etal-2018" /><ref name="Ferrais-Vernazza-etal-2020" /><ref name="Shepard2021" /><ref name="Vernazza2021" /> The most recent models show that Psyche has a shape consistent with a Jacobi ellipsoid and dimensions within a few km of 278 km x 238 km x 171 km.<ref name="Viikinksk-Vernza-etal-2018" /><ref name="Vernazza2021" /><ref name="Shepard2021" /><ref name="Ferrais-Vernazza-etal-2020" />

Each shape model provides an estimate of the direction of the north pole (spin axis). All recent models for Psyche suggest it rotates about a pole pointed towards the ecliptic coordinates (long, lat) Template:Nowrap, Template:Nowrap, with a 3° uncertainty.<ref name="Hanuš-Viikinksk-etal-2017"/><ref name="Shepard-Richardson-etal-2017" /><ref name="Drummond_etal_2018" /><ref name="Viikinksk-Vernza-etal-2018" /><ref name="Ferrais-Vernazza-etal-2020" /><ref name="Shepard2021" /> This means that it is essentially tilted toward the ecliptic, with an axial tilt of 98°.

Template:Multiple image

FeaturesEdit

File:Psyche illustration.jpg

Illustration of Psyche commissioned by NASA

Many features have been reported on Psyche. The largest of these are regions of mass-deficits relative to its nominal ellipsoid shape and are reminiscent of the Rheasilvia basin on 4 Vesta.<ref name="Shepard2021" /><ref name="Ferrais-Vernazza-etal-2020" /><ref name="Viikinksk-Vernza-etal-2018" /><ref name="Shepard-Richardson-etal-2017" />

In addition to the large-scale regions of mass-deficit, several apparent craters have been reported. Observers using the Very Large Telescope's adaptive optics SPHERE imager reported two large craters, on the order of 90 km across, which were provisionally named Meroe Template:IPAc-en and Panthia Template:IPAc-en,Template:Citation needed after the twin witches in the Roman novel Metamorphoses by Apuleius.<ref name="Zimmerman_mythology"/><ref name=Viikinksk-Vernza-etal-2018/> Observers using the Arecibo Radar Telescope reported craters at the south pole (referred to as Delta),<ref name="Shepard-Richardson-etal-2017" /> southern midlatitudes (referred to as Eros),<ref name="Shepard-Richardson-etal-2017" /><ref name="Shepard2021" /> and the north pole (referred to as Foxtrot).<ref name="Shepard2021" /> An analysis of the features present in several independent shape models suggests that craters Panthia and Eros are almost certainly real and Foxtrot is likely to be real. However, there is uncertainty over the existence of Meroe and Delta.<ref name="Shepard2021" />

Early lightcurve studies suggested that Psyche has large variations in its surface brightness.<ref name="Dotto1992"/> These variations became more evident when attempts were made to invert lightcurves to generate shape models.<ref name="Kaasalainen-etal-2002" /><ref name="Shepard-Richardson-etal-2017" /> The most recent shape models based on lightcurve inversions simultaneously solve for surface albedo variations,<ref name="Viikinksk-Vernza-etal-2018" /><ref name="Ferrais-Vernazza-etal-2020" /> and the resulting maps show regions where local albedo differs from the mean albedo by more than 20% in either direction. Notably, the Meroe crater coincides with an area much darker than the mean, and the Panthia crater coincides with an area much brighter than the mean.

Radar observations with the Arecibo Radar Telescope revealed that Psyche's "background" radar albedo is <math>\hat{\sigma}_{OC}=0.26 </math>, comparable to other M-type asteroids like 21 Lutetia.<ref name="Shepard2021" /> This value is consistent with a silicate (rocky) regolith enriched in metal phases.<ref name="Shepard2015"/> However, in at least three locations, Psyche's radar albedo is nearly twice this value, suggesting high concentrations of metal phases in these regions.<ref name="Shepard2021" /> One of these locations corresponds with the optically bright Panthia crater, while the other two correspond with regions that have been reported as optically bright.<ref name="Ferrais-Vernazza-etal-2020" /><ref name="Viikinksk-Vernza-etal-2018" /><ref name="Shepard2021" /> This apparent correlation between optical and radar albedos on Psyche has led to the hypothesis that there is a link between the process(es) that create regions of high metal content and brighter terrain.<ref name="Shepard2021" />

Template:Multiple image

CompositionEdit

The bulk density of Psyche (Template:Val) places constraints on its overall composition. The iron-nickel found in most iron meteorites has a bulk density of Template:Val. If Psyche were the remnant core of an early planetesimal, it would have to have an overall porosity of 50%. Given Psyche's size, this is considered highly improbable.<ref name="Elkins-Tanton_2020" /> However, there are other metal-rich meteorite types that have been suggested as Psyche analogs, each of which have bulk densities that are similar to Psyche's, including enstatite chondrites, bencubbinites, and mesosiderites.<ref name="Gaffey_asteroidsII" /><ref name="Viikinksk-Vernza-etal-2018" /><ref name="Elkins-Tanton_2020" />

Several observers have reported the presence of silicate minerals on the surface of Psyche.<ref name="Hardersen-Gaffey-Abell-2005" /><ref name="Ockert-Bell"/><ref name="Sanchez"/> Spectra taken in October 2016 at the NASA Infrared Telescope Facility at the Mauna Kea Observatories showed evidence (~3 μm absorption feature) of hydroxyl ions on the asteroid that may suggest the presence of hydrated silicates.<ref name=Takir-Reddy-etal-2016/> Since Psyche is thought to have formed under dry conditions without the presence of water, the hydroxyl may have reached Psyche via past impacts from smaller carbonaceous asteroids.<ref name=Takir-Reddy-etal-2016/><ref name="Shepard2015" />

Psyche's radar albedo varies considerably over the surface, ranging from 0.22 to 0.52,<ref name="Shepard2021" /> values that are two to four times as high as most main-belt asteroids.<ref name="Magri2007"/> Models of radar reflection equate this range of values with regolith bulk densities of 2.6 to 4.7 Template:Val.<ref name="Shepard2015" /> This range is consistent with most of the metal-rich meteorite classes noted above and the spectroscopic detection of silicate minerals. It is inconsistent with a pure iron-nickel regolith unless it is highly porous.

File:16 Psyche orbit.png

The orbit of Psyche, between Mars and Jupiter, with eccentricity of 0.140: much higher than most planets, but typical for an asteroid.

OriginEdit

Several possible origins have been proposed for Psyche. The earliest of these was that Psyche is an exposed metallic core resulting from a collision that stripped away the crust and mantle of an originally larger differentiated parent body some 500 kilometers in diameter.<ref name="Bell_AsteroidsII" /> Other versions of this include the idea that it was not the result of a single large collision but multiple (more than three) relatively slow sideswipe collisions with bodies of comparable or larger size.<ref name=Asphaug-Reufer-2014/> However, this idea has fallen out of recent favor as mass and density estimates are inconsistent with a remnant core.<ref name="Elkins-Tanton_2020" />

A second hypothesis is that Psyche was disrupted and gravitationally re-accreted into a mix of metal and silicate.<ref name=Davis-Farinella-Francesco-1999/> In this case, it may be a candidate for the parent body of the mesosiderites, a class of stony–iron meteorites.<ref name=Davis-Farinella-Francesco-1999/>

A third hypothesis is that Psyche may be a differentiated object, like 1 Ceres and 4 Vesta, but has experienced a type of iron volcanism, also known as ferrovolcanism, while still cooling.<ref name="Johnson_ferrovolcanism"/> If true, this model predicts that metal would be highly enriched only in those regions containing (relic) volcanic centers. This view has been bolstered by recent radar observations.<ref name=Shepard2021/>

ExplorationEdit

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File:PIA21499 - Artist's Concept of Psyche Spacecraft with Five-Panel Array.jpg

Artist's concept of the Psyche spacecraft orbiting asteroid Psyche

No spacecraft has visited Psyche, but a mission to Psyche was proposed to NASA in 2014.<ref name=Chang-2017-01-06-NYT/><ref name=Wall-2014-01-15/> A team led by Lindy Elkins-Tanton,<ref name=ElkinsTr-Asphaug-etal-2014/> the director of the School for Earth and Space Exploration at Arizona State University, presented a concept for a robotic Psyche orbiter. This team argued that 16 Psyche would be a valuable object for study because it is the only metallic core-like body discovered so far.<ref name=Wall-2014-01-15/>

The spacecraft would orbit Psyche for 20 months,<ref name=Chang-2017-01-06-NYT/> studying its topography, surface features, gravity, magnetism, and other characteristics and would be based on current technology, avoiding high cost and the necessity to develop new technologies. On 30 September 2015, the Psyche orbiter mission was one of five Discovery Program semifinalist proposals.<ref name=Brown-Cantillo-2015-09-30-pr/>

The mission was approved by NASA on 4 January 2017 and was originally targeted to launch in October 2023, with an Earth gravity assist maneuver in 2024, a Mars flyby in 2025, and arriving at the asteroid in 2030.<ref name=Northon-2017-01-04-pr/> In May 2017, the launch date was moved up to target a more efficient trajectory, launching in 2022, with a Mars gravity assist in 2023 and arriving in 2026.<ref name=NASA-2017-05-24-pr/> However, problems with Psyche's flight software led NASA to revert to the original launch timeline.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

On 28 February 2020, NASA awarded SpaceX a US$117 million contract to launch the Psyche spacecraft, and two smallsat secondary missions, on a Falcon Heavy rocket.<ref name=Foust-2020-02-28/> The spacecraft was successfully launched on 13 October 2023, at 14:19 UTC,<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> with an expected arrival in 2029.<ref name = "jpl-20221028" />

Asteroid Psyche has an Earth-MOID of Template:Convert,<ref name="JPL"/> and most recently came to opposition on 6 August 2024 when it was Template:Convert from Earth.<ref name="Opposition2024"/>

NotesEdit

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ReferencesEdit

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External linksEdit

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