Comet tail

In the outer Solar System, comets remain frozen and are extremely difficult or impossible to detect from Earth due to their small size. Statistical detections of inactive comet nuclei in the Kuiper belt have been reported from the Hubble Space Telescope observations,^[4][5] but these detections have been questioned,^[6][7] and have not yet been independently confirmed. As a comet approaches the inner Solar System, solar radiation causes the volatile materials within the comet to vaporize and stream out of the nucleus, carrying dust away with them. The streams of dust and gas thus released form a huge, extremely tenuous atmosphere around the comet called the coma, and the force exerted on the coma by the Sun's radiation pressure and solar wind cause an enormous tail to form, which points away from the Sun.

The streams of dust and gas each form their own distinct tails, pointing in slightly different directions. The gas or ion tail, which follows the magnetic field lines, is quite narrow and straight. After perihelion, the comet's dust tail may become strongly curved to such a degree that, as seen from the perspective of the Earth, parts of it appear to lie on the sunward side of the nucleus forming what is known as an anti-tail or anomalous tail.^[8]

While the solid nucleus of comets is generally less than 30 km across, the coma may be larger than the Sun, and ion tails have been observed to extend 3.8 astronomical units (570 Gm; 350×10^⁶ mi).^[9]

The structure of the ion tail is the result of complex interactions between the Sun and the comet. Ultraviolet radiation ionize molecules in the coma, forming plasma which in turn induces a magnetosphere around the comet. The comet and its induced magnetic field form an obstacle to solar wind particles. The comet is supersonic relative to the solar wind, so a bow shock is formed upstream of the comet (i.e. facing the Sun), in the flow direction of the solar wind. In this bow shock, large concentrations of cometary ions (called "pick-up ions") congregate and act to "load" the solar magnetic field with plasma. The field lines "drape" around the comet forming the ion tail.^[10]: 898

If the ion tail loading is sufficient, then the magnetic field lines are squeezed together to the point where, at some distance along the ion tail, magnetic reconnection occurs. This leads to a "tail disconnection event".^[10] This has been observed on a number of occasions, notable among which was on April 20, 2007, when the ion tail of comet Encke was completely severed as the comet passed through a coronal mass ejection.^[11] This event was observed by the STEREO spacecraft.^[12] A disconnection event was also seen with C/2009 R1 (McNaught) on May 26, 2010.^[13]

Venus possesses a similar tail due to the induced magnetosphere formed by interaction of the solar wind with the venusian atmosphere. On January 29, 2013, ESA scientists reported that the ionosphere of the planet Venus streams outwards in a manner similar to "the ion tail seen streaming from a comet under similar conditions."^[14][15] While Mercury lacks an atmosphere, the MESSENGER mission observed magnesium and sodium flowing off the planet, along the magnetic field lines trailing behind the planet, making them the primary components of Mercury's magnetotail.^{[16][citation needed]}

Dust particles emitted from a comet nucleus are acted upon by the attractive force of gravity, ${\displaystyle F_{\textrm {grav}}}$, and the repulsive force of solar radiation, ${\displaystyle F_{\textrm {rad}}}$. Both of the forces vary as the inverse square of the distance from the Sun. The net effect is that an emitted dust particle experiences and effective reduction in the force of gravity parameterized by ${\displaystyle \beta =F_{\textrm {rad}}/F_{\textrm {grav}}}$ and on leaving the neighborhood of the comet nucleus follows its own individual Keplerian orbit. Larger, heavier dust particles are less affected by solar radiation pressure and are characterized by smaller values of ${\displaystyle \beta }$.

In 1968, Finson and Probstein^[17] developed an effective model for the observable properties of a comet tail. Their method relies on combining a function for the rate of dust production from the nucleus with functions for the size distribution of particles and their ejection velocity distribution.^[18] They applied their methods to comet C/1956 R1 (Arend-Roland).^[19] Their first paper laid out a framework for computing the trajectories of the comet and ejected dust particles. Sekanina employed this approach to successfully predict the appearance of anti-tails in comets C/1973 E1 (Kohoutek)^[20] and C/1975 V2 (Bradfield).^[21]

The Finson-Probstein (F-P) diagram on the right is for Comet Arend-Roland on April 28, 1957 about 2 days after the Earth crossed the comet's orbital plane. The view is looking down on the orbital plane. The solid lines are synchrones which represent streams of particles emitted at the same time with smaller, lighter particles (those with larger ${\displaystyle \beta }$) travelling further from the nucleus. The synchrones are labeled with the time in days since their emission. The dotted lines represent syndynes which connect dust particles with the same value of ${\displaystyle \beta }$ emitted at different times in the past. The synchrones are labeled with ${\displaystyle \beta }$. The blue and orange arrows indicate the directions of the Earth and Sun respectively. The comet's orbital path is plotted in gray.

The other F-P diagram shows the view as seen from Earth. Both F-P diagrams were previously plotted by Sekanina.^[20] Notice, from this perspective, that part of the dust tail appears in the sunward direction from the nucleus which produces an anti-tail. There is a considerable piling up of older synchrones producing the observed sharp edge on to the anti-tail. Younger synchrones are also crowded together while those of intermediate ages are spread out over a broad area of sky making the tail fainter in this region and giving the impression that the it is split into a main branch and a sunward branch.

Dust particles ejected isotropically from the comets nucleus follow their own Keplerian orbit, each specified by their own set of orbital elements. The orbits are, in general, inclined to the comet's orbital plane and the particles will initially move away from it. However, upon reaching a point in their orbit on the other side of Sun from where they were ejected, they will have returned and cross the orbital plane. This happens when the dust particle's true anomaly, ${\displaystyle \nu }$, has increased by 180${\displaystyle ^{\circ }}$ (${\displaystyle \pi }$ radians) from its initial value on ejection. The crossing is described as reaching its second node. This behavior is represented stylistically in the diagram. In it the Sun is the orange ball and the comet's nucleus is shown in green. The orbital plane is shaded blue and the comet's orbital is shown in gray. The ejected shell of dust particles remains spherical for only a short period of time and soon becomes ellipsoidal. While continuing to expand in directions parallel to the orbital plane it reaches a maximum extent perpendicular to the plane before contracting to become a planar ellipse as the dust particles pass through the orbital plane at their second nodes. After that the ellipsoid again expands. The animation shows a Monte-Carlo simulation for a shell of 2,000 dust particles with ${\displaystyle \beta }$=0.03 ejected by C/1956 R1 (Arend-Roland) at a speed of 360 m/s on 17 March 1957 at 21:36 UT as seen by an observer following the comet outside of its orbit and looking in the direction of the Sun. The time since ejection, ${\displaystyle \Delta T}$, and true anomaly, ${\displaystyle \nu }$, are displayed.^[22]

Shells of dust particles with different values of ${\displaystyle \beta }$ form their own distinct planar ellipses slightly displaced from one another and are known collectively as the neck-line structure (NLS). A couple of notable features of these ellipses. Its outer edge is formed by particles ejected parallel to the orbital plane. A particle with the same value of ${\displaystyle \beta }$ emitted from the nucleus at zero relative velocity would lie in the geometric center of the ellipse. The center of the ellipse therefore sits at the intersection of the associated synchrone and syndyne. Typically therefore much of the NLS is embedded in the normal dust tail. The NLS can only form after perihelion passage and its flatness means that it is best seen as the Earth crosses the comet's orbital plane.

The F-P diagram for comet C/2023 A3 (Tsuchinshan-ATLAS) is shown for 14 October 2024 at 18:30 UT when the Earth crossed its orbital plane. Also shown are red, orange, yellow, green and blue planar ellipses for dust particles with ${\displaystyle \beta }$ = 0.01, 0.02, 0.03, 0.04 and 0.05 respectively ejected 64.5 days earlier. Most of the NLS lies outside of the comet's orbit (on the anti-sunward side), but some of the heaviest dust particles lie in a shorter spike on the sunward side. The sunward spike is short (a few arc mins to half a degree) while the tailward feature can be much longer (several degrees).^[23] Pansecchi et al^[24] coined the term sunward spike (SWS) for that part of the NLS falling on the sunward side of the orbit and ray-shaped structure (RSS) for the remainder. Because it is generally seen projected on the normal dust tail early attempts required careful microdensitometer measurements of photographic plates.^[24][25]

The term anti-tail can be ambiguous but here will be used to refer to any tail-like extension seen as emanating from the comet's nucleus in the sunward direction. There are a number of mechanisms that cause a sunward anti-tail to appear.

Cometary dust trails are long-lived streams of large grains (>0.1mm) ejected from comet nuclei at low velocities and closely follow its orbital trajectory. These large grains are more efficient at emitting heat than scattering sunlight at visible wavelengths. Dust Trails were first observed directly by the Infrared Astronomical Satellite (IRAS)^[2] and later by the Spitzer Space Telescope.^[40] As of 2021 there were 44 comets that were known to have dust trails.^[3]

The wide-field views and long cointegration times provided by the Transiting Exoplanet Survey Satellite (TESS) have lead to several dust trail discoveries and will potentially yield many more.^[41]

Dust trails that intersect the Earth's orbit produce recurrent meteor showers.

Wikimedia Commons has media related to Comet tails.

• Finson-Probstein diagrams for comets viewed from Earth can be produced online using J.-B. Vincent's Comet-toolbox
• Comets page at NASA's Solar System Exploration
• International Comet Quarterly at Harvard.edu
• 1957 photo of Comet Arend–Roland showing a prominent anti-tail