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Messier 106
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| Messier 106 | |
|---|---|
 | |
| Observation data (J2000 epoch) | |
| Constellation | Canes Venatici |
| Right ascension | 12h 18m 57.5s[1] |
| Declination | +47° 18′ 14″[1] |
| Redshift | 448 ± 3 km/s[1] |
| Distance | 23.7 ± 1.5 Mly (7 ± 0.5 Mpc)[2][3] |
| Apparent magnitude (V) | 8.4[1] |
| Characteristics | |
| Type | SAB(s)bc[1] |
| Size | 151,700 ly (46.53 kpc) (estimated)[1][4] |
| Apparent size (V) | 18′.6 × 7′.2[1] |
| Notable features | Megamaser galaxy,[5] Seyfert II galaxy.[6] |
| Other designations | |
| M 106, NGC 4258, UGC 7353, PGC 39600.[1][7] | |
Messier 106 (also known as NGC 4258) is an intermediate spiral galaxy in the constellation Canes Venatici. It was discovered by Pierre Méchain in 1781. M106 is at a distance of about 22 to 25 million light-years away from Earth. M106 contains an active nucleus classified as a Type 2 Seyfert, and the presence of a central supermassive black hole has been demonstrated from radio-wavelength observations of the rotation of a disk of molecular gas orbiting within the inner light-year around the black hole.[8] NGC 4217 is a possible companion galaxy of Messier 106.[7] Besides the two visible arms, it has two "anomalous arms" detectable using an X-ray telescope.
Characteristics
[edit]M106 has a water vapor megamaser (the equivalent of a laser operating in microwave instead of visible light and on a galactic scale) that is seen by the 22-GHz line of ortho-H2O that evidences dense and warm molecular gas. Water masers are useful for observing nuclear accretion disks in active galaxies. The water masers in M106 enabled the first case of a direct measurement of the distance to a galaxy, thereby providing an independent anchor for the cosmic distance ladder.[9][10] M106 has a slightly warped, thin, almost edge-on Keplerian disc which is on a subparsec scale. It surrounds a central area with mass 4×107 M☉.[11]
It is one of the largest and brightest nearby galaxies, similar in size and luminosity to the Andromeda Galaxy.[12] The supermassive black hole at the core has a mass of (3.9±0.1)×107 M☉.[13]
M106 has also played an important role in calibrating the cosmic distance ladder. Before, Cepheid variables from other galaxies could not be used to measure distances since they cover ranges of metallicities different from the Milky Way's. M106 contains Cepheid variables similar to both the metallicities of the Milky Way and other galaxies' Cepheids. By measuring the distance of the Cepheids with metallicities similar to our galaxy, astronomers are able to recalibrate the other Cepheids with different metallicities, a key fundamental step in improving quantification of distances to other galaxies in the universe.[3]
Supernovae
[edit]Two supernovae have been observed in M106:
- SN 1981K (Type II, mag. 17) was reported by E. Hummel and verified by Paul Wild by examining archival photos dated 3 November 1981.[14][15]
- SN 2014bc (Type II, mag. 14.8) was discovered by the PS1 Science Consortium 3Pi survey on 19 May 2014.[16][17][18]
See also
[edit]References
[edit]- ^ a b c d e f g h "NASA/IPAC Extragalactic Database". Results for Messier 106. Retrieved 7 December 2006.
- ^ Tonry, J. L.; et al. (2001). "The SBF Survey of Galaxy Distances. IV. SBF Magnitudes, Colors, and Distances". Astrophysical Journal. 546 (2): 681–693. arXiv:astro-ph/0011223. Bibcode:2001ApJ...546..681T. doi:10.1086/318301. S2CID 17628238.
- ^ a b Macri, L. M.; et al. (2006). "A New Cepheid Distance to the Maser-Host Galaxy NGC 4258 and Its Implications for the Hubble Constant". Astrophysical Journal. 652 (2): 1133–1149. arXiv:astro-ph/0608211. Bibcode:2006ApJ...652.1133M. doi:10.1086/508530. S2CID 15728812.
- ^ http://freestarcharts.com/index.php/20-guides/messier/262-messier-106-m106-spiral-galaxy freestarcharts
- ^ Bonanos, Alceste Z. (2006). "Eclipsing Binaries: Tools for Calibrating the Extragalactic Distance Scale". Proceedings of the International Astronomical Union. 2 (S240): 79–87. arXiv:astro-ph/0610923. Bibcode:2007IAUS..240...79B. doi:10.1017/S1743921307003845. S2CID 18827791.
- ^ Humphreys, E. M. L.; et al. (2004). "Improved Maser Distance to NGC 4258". Bulletin of the American Astronomical Society. 36: 1468. Bibcode:2004AAS...205.7301H.
- ^ a b "M 106". SIMBAD. Centre de données astronomiques de Strasbourg. Retrieved 7 December 2006.
- ^ Miyoshi, Makoto; et al. (12 January 1995). "Evidence for a black hole from high rotation velocities in a sub-parsec region of NGC4258". Nature. 373 (6510): 127–129. Bibcode:1995Natur.373..127M. doi:10.1038/373127a0. S2CID 4336316.
- ^ Herrnstein, J. R.; et al. (1999). "A geometric distance to the galaxy NGC 4258 from orbital motions in a nuclear gas disk". Nature. 400 (6744): 539–541. arXiv:astro-ph/9907013. Bibcode:1999Natur.400..539H. doi:10.1038/22972. S2CID 204995005.
- ^ de Grijs, Richard (2011). An Introduction to Distance Measurement in Astronomy. Chichester: John Wiley & Sons. p. 109. ISBN 978-0-470-51180-0.
- ^ Henkel, C.; et al. (2005). "New H2O masers in Seyfert and FIR bright galaxies". Astronomy and Astrophysics. 436 (1): 75–90. arXiv:astro-ph/0503070. Bibcode:2005A&A...436...75H. doi:10.1051/0004-6361:20042175. S2CID 117098659.
- ^ Karachentsev, Igor D.; Karachentseva, Valentina E.; Huchtmeier, Walter K.; Makarov, Dmitry I. (2003). "A Catalog of Neighboring Galaxies". The Astronomical Journal. 127 (4): 2031–2068. Bibcode:2004AJ....127.2031K. doi:10.1086/382905.
- ^ Graham, Alister W. (November 2008). "Populating the Galaxy Velocity Dispersion – Supermassive Black Hole Mass Diagram: A Catalogue of (Mbh, σ) Values". Publications of the Astronomical Society of Australia. 25 (4): 167–175. arXiv:0807.2549. Bibcode:2008PASA...25..167G. doi:10.1071/AS08013. S2CID 89905.
- ^ Hummel, E.; Van Der Hulst, J. M.; Davies, R. D.; Pedlar, A.; Van Albada, G. D.; Wild, P. (1983). "Possible Supernova in NGC 4258". International Astronomical Union Circular (3803): 2. Bibcode:1983IAUC.3803....2H.
- ^ "SN 1981K". Transient Name Server. IAU. Retrieved 4 December 2024.
- ^ Smartt, S. J.; et al. (2014). "Supernova 2014bc in M106 = PSN J12185771+4718113". Central Bureau Electronic Telegrams (3876): 1. Bibcode:2014CBET.3876....1S.
- ^ "SN 2014bc". Transient Name Server. IAU. Retrieved 4 December 2024.
- ^ Zheng, Weikang; Filippenko, Alexei V. (2014). "KAIT Prediscovery Detection of PS1-14xz in NGC 4258 (Messier 106)". The Astronomer's Telegram. 6159: 1. Bibcode:2014ATel.6159....1Z.
External links
[edit]
Wikimedia Commons has media related to Messier 106.
- StarDate: M106 Fact Sheet
- Spiral Galaxy M106 at SEDS Messier pages
- Messier 106 on WikiSky: DSS2, SDSS, GALEX, IRAS, Hydrogen α, X-Ray, Astrophoto, Sky Map, Articles and images
- NGC 4258: Mysterious Arms Revealed
- Spiral Galaxy Messier 106 (NGC 4258) at the astro-photography site of Takayuki Yoshida
- Nemiroff, R.; Bonnell, J., eds. (19 March 2011). "Messier 106". Astronomy Picture of the Day. NASA.
- Nemiroff, R.; Bonnell, J., eds. (3 May 2012). "Messier 106". Astronomy Picture of the Day. NASA.
- Messier 106 at Constellation Guide
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Messier 106
View on Grokipediafrom Grokipedia
Discovery and Cataloging
Historical Discovery
Messier 106 was first identified by the French astronomer Pierre Méchain on July 17, 1781, during a systematic search for comets in the constellation Canes Venatici.[7] As a key collaborator of Charles Messier, Méchain routinely shared his findings, noting the object as a faint nebula situated near the "haunches of the Great Bear." Despite this communication, the discovery was not incorporated into Messier's original catalog, likely due to its subdued brightness and the focus on more prominent comet-like objects at the time.[8] Charles Messier himself did not independently confirm or observe the nebula during his lifetime, and it remained outside the initial Messier compilation published later that year.[4] The object's elusive nature contributed to its omission, as Messier prioritized verifiable, distinct features to aid comet hunters in distinguishing true comets from fixed celestial bodies. Méchain's report highlighted its nebulous appearance without resolved stars, aligning with the era's understanding of such diffuse patches as non-stellar phenomena.[9] The nebula was independently rediscovered by British astronomer William Herschel on March 9, 1788, using his superior 20-foot reflector telescope. Herschel cataloged it as H V.43, describing it as "very brilliant" with a "bright nucleus" and faint, milky branches extending northward and southward, emphasizing its structured luminosity.[10] His detailed sketch and notes marked one of the earliest telescopic portrayals, revealing more about its elongated form than Méchain's initial sighting. In 1947, Canadian astronomer Helen Sawyer Hogg formally added the object to the extended Messier catalog as M106, recognizing it as one of seven overlooked discoveries by Méchain, thereby honoring the original finder's contribution posthumously.[7] This addition solidified its place in astronomical history, preceding its 20th-century reclassification from nebula to spiral galaxy.Catalog Designation and Early Observations
Although discovered in 1781 and added to the extended Messier catalog in 1947 as M106, the galaxy was systematically cataloged in subsequent astronomical surveys under other designations. In the New General Catalogue published in 1888 by J.L.E. Dreyer, it was assigned the designation NGC 4258, drawing primarily from positional observations made by John Herschel during his surveys in the 1820s and 1830s with telescopes at the Cape of Good Hope and in England. This entry refined earlier descriptions by providing precise coordinates and descriptions of its nebulous, extended form, integrating it into a comprehensive inventory of non-stellar objects that built upon Herschel's foundational work. Significant early visual observations came in 1848 from William Parsons, 3rd Earl of Rosse, who employed his revolutionary 72-inch reflector, the Leviathan telescope, at Birr Castle in Ireland. Rosse's detailed sketches and notes described NGC 4258 as a "very large bright extended nebula; much mottled," resolving faint branches and for the first time discerning its spiral structure amid the mottled luminosity, which hinted at its organized form beyond simple nebulosity.[12] These observations, among Rosse's broader study of spiral nebulae, marked a pivotal advancement in resolving the internal architecture of such objects with then-unprecedented aperture and resolution. Advancing into the early 20th century, spectroscopic analysis by Vesto Slipher at Lowell Observatory in 1914 provided crucial dynamical insights into NGC 4258. Using a 24-inch refractor equipped with a high-dispersion spectrograph, Slipher measured the galaxy's radial velocity at approximately +500 km/s, revealing a substantial recession that aligned with patterns in other spiral nebulae and supported their interpretation as distant, extragalactic systems rather than local gaseous clouds within the Milky Way. By the 1940s, further spectroscopic scrutiny classified NGC 4258 within a new category of active galaxies. In his seminal 1943 study, Carl K. Seyfert examined the emission-line spectra of several bright-nuclei spirals, including NGC 4258, noting intense, high-excitation lines from the nucleus indicative of energetic processes distinct from typical galactic emission. This work established the class now known as Seyfert galaxies, with NGC 4258 exemplifying Type 2 characteristics through its prominent forbidden lines and lack of broad permitted emission, highlighting nuclear activity driven by non-thermal mechanisms.Location and Observational Details
Coordinates and Visibility
Messier 106 is positioned at equatorial coordinates of right ascension 12h 18m 57.5s and declination +47° 18′ 14″ in the J2000 epoch.[2] This places it in the constellation Canes Venatici, near the border with Ursa Major.[13] With an apparent visual magnitude of 8.4 and an angular size of 18.7 × 7.6 arcminutes, Messier 106 appears as a faint, elongated glow in binoculars and small telescopes but readily observable in amateur telescopes of 4-inch aperture or larger, provided light pollution is minimal.[8][7] Its brightness makes it a suitable target for binoculars from mid-northern latitudes, where it culminates high in the sky during optimal viewing periods. The galaxy is best observed during spring months, particularly from late March to early June, when it reaches opposition and is well-placed for northern hemisphere observers at latitudes above 30°N.[13] At a distance of approximately 24 million light-years, this positioning contributes to its moderate apparent brightness despite its intrinsic luminosity.[13] To locate Messier 106, start from Phecda (γ Ursae Majoris), the southeastern star in the Big Dipper's bowl, and sweep about 10° southeast; it lies roughly halfway toward the bright star Chara (β Canum Venaticorum) in Canes Venatici. Under good conditions, it presents as a hazy, spindle-shaped patch oriented nearly north-south, with a brighter core hinting at its spiral structure.Distance and Redshift
Messier 106, also known as NGC 4258, has a current distance estimate of 7.6 million parsecs (Mpc), or approximately 24.8 million light-years, derived primarily from geometric measurements of water maser emissions in its circumnuclear disk, with Cepheid variable stars providing a consistent independent calibration. Observations of Cepheid variables in the galaxy using the Hubble Space Telescope (HST) during the 1990s and 2000s refined this distance by establishing a period-luminosity relation tied to the Large Magellanic Cloud, yielding a distance modulus of 29.40 ± 0.07 magnitudes. These HST-based Cepheid measurements, involving over 280 identified variables with periods between 4 and 45 days, achieved a precision of about 5% and aligned closely with the maser-derived value, enhancing confidence in the overall estimate.[14][15] This proximity and robust distance measurement position Messier 106 as a key anchor in the cosmic distance ladder, serving to calibrate Cepheid distances in more remote galaxies and, by extension, standardize luminosities of Type Ia supernovae for probing the Hubble constant. Specifically, the well-measured Cepheids in Messier 106 allow for metallicity-independent period-luminosity relations that anchor supernova distances out to hundreds of megaparsecs, reducing systematic uncertainties in extragalactic distance scales.[16][17] The galaxy exhibits a redshift of , corresponding to a heliocentric recessional velocity of approximately 450 km/s, which follows Hubble's law for nearby objects when accounting for local peculiar motions. This low redshift places Messier 106 within the local supercluster's influence, where deviations from pure Hubble flow arise due to gravitational interactions, but the velocity remains broadly consistent with an expansion rate of km/s/Mpc given its distance.[18] Historical distance estimates for Messier 106 have undergone significant revision, starting from roughly 20 million light-years in the 1980s based on early surface brightness fluctuation and Tully-Fisher methods, which carried uncertainties exceeding 20%. Post-HST Cepheid observations in the late 1990s and early 2000s, combined with high-precision maser mapping, narrowed the value to the current 7.6 Mpc with under 5% error, highlighting the impact of space-based photometry on nearby galaxy distances.Physical Characteristics
Morphology and Structure
Messier 106, also known as NGC 4258, is classified as an intermediate spiral galaxy of type SABbc according to the de Vaucouleurs system, indicating a weakly barred structure with moderately wound spiral arms and a classical bulge.[19] This classification highlights its transitional nature between unbarred and strongly barred spirals, with the weak bar spanning the inner region and contributing to the overall dynamics of the disk.[19] The prominent spiral arms extend from the ends of the bar, forming a symmetric pattern that dominates the galaxy's optical appearance, while the central bulge appears bright and compact in visible light.[6] The galactic disk of Messier 106 measures approximately 40 kpc in diameter, corresponding to about 123,000 light-years when scaled to its distance of 7.2 Mpc, and is rich in gas and dust that delineates its structure.[19] The spiral arms are tightly wound, exhibiting clear dust lanes that trace the density waves and host clusters of young, massive stars indicative of ongoing star formation.[6] These arms, visible in both optical and near-infrared wavelengths, show enhanced emission from polycyclic aromatic hydrocarbons (PAHs) and ionized gas, underscoring regions of active processing of interstellar material.[20] High-resolution infrared observations from the James Webb Space Telescope's NIRCam instrument reveal intricate details of the inner architecture, including a circumnuclear ring of star-forming regions approximately 4.8 kpc in diameter, offset from the nucleus.[20] Complementary radio imaging from the Very Large Array further maps the inner disk, highlighting molecular gas distributions and the weak bar's influence on the circumnuclear environment.[20] This inner disk, encompassing the central bulge, displays a complex interplay of dust and gas, with the ring serving as a reservoir for material funneled inward by the bar. The disk is inclined at approximately 72° to the line of sight.[21][22] In comparison to the Milky Way, which shares a similar SABbc classification and disk size of around 100,000 light-years, Messier 106 exhibits analogous spiral morphology but with a more evident weak bar and heightened dust prominence in its arms.[20][23]Size, Mass, and Rotation
Messier 106 exhibits a total diameter of approximately 135,000 light-years across its outer halo, as determined from its angular extent and distance measurements. The stellar disk, corresponding to the optical isophote at 25 mag/arcsec², spans roughly 124,000 light-years (38 kpc) in diameter, reflecting the extent of the luminous component before transitioning to the more extended neutral hydrogen envelope. These dimensions position Messier 106 as a large spiral galaxy comparable in scale to the Milky Way. The estimated total dynamical mass of Messier 106 is 2–4 × 10^{11} solar masses, primarily derived from analysis of its rotation curve, which reveals a flat velocity profile extending to large radii and indicative of an underlying dark matter halo contributing significantly to the mass budget beyond the central regions. This mass encompasses both baryonic and dark components within the virial radius, with the flat rotation curve suggesting that dark matter dominates the gravitational potential at outskirts, preventing the expected Keplerian decline in orbital speeds. Early spectroscopic studies of emission lines confirmed a mass of about 1.5 × 10^{11} solar masses within 30 kpc, while extensions to the HI disk support the higher total estimate.[24] Rotation speeds in Messier 106 reach about 230 km/s at the outskirts, as mapped through neutral hydrogen (HI) 21 cm radio observations that trace the galactic disk to large radii. These measurements show a nearly flat rotation curve from approximately 3 to 7 arcminutes, consistent with a massive halo providing stable orbital support. The inclination of the galaxy disk to the line of sight is approximately 72°, which corrects projected velocities in the rotation curve and affects apparent size estimates along the minor axis. Dynamical mass estimates incorporate this geometry via the orbital velocity formula: where is the rotation velocity, is the gravitational constant, is the enclosed mass, and is the radial distance; applying this to HI data at large yields the total mass scale while accounting for the inclination-derived deprojection.[25]Active Nucleus
Supermassive Black Hole
At the center of Messier 106 (NGC 4258) resides a supermassive black hole that powers the galaxy's active nucleus. This black hole is located precisely at the galactic center and exhibits evidence of accretion activity through bright X-ray emissions from its surrounding hot corona and powerful radio jets emanating from the nucleus.[26][27] The jets, observed in radio wavelengths, extend outward and interact with the interstellar medium, producing shocks detectable in X-rays, which confirm the black hole's role in driving the energetic output of the active galactic nucleus.[28] The mass of this supermassive black hole is solar masses, determined through high-precision measurements of water megamaser dynamics in a thin, Keplerian accretion disk surrounding the black hole.[27] These observations utilized very long baseline interferometry (VLBI) techniques, primarily with the Very Long Baseline Array (VLBA), conducted during the 1990s and 2000s to map the positions and velocities of maser spots in the disk.[29] The masers trace orbital motions at radii of approximately 0.1–0.3 parsecs from the black hole, allowing for direct dynamical constraints on its mass. The first precise measurement came from VLBA observations reported in 1995 by Miyoshi et al., who analyzed the Keplerian rotation of the maser-emitting gas to infer a central mass concentration consistent with a supermassive black hole.[29] Subsequent refinements, incorporating improved distance estimates to Messier 106 and additional maser data, confirmed the mass value with an uncertainty of about 3%.[27] The black hole mass is calculated using the formula for Keplerian orbits: where is the orbital velocity of the masers derived from Doppler shifts, is the orbital radius obtained from the angular positions and the galaxy's distance, and is the gravitational constant.[29] This method provides one of the most accurate direct mass determinations for any extragalactic supermassive black hole, serving as a benchmark for calibration in broader studies of black hole demographics.Seyfert Activity and Megamasers
Messier 106, also known as NGC 4258, was among the first galaxies identified with an active nucleus exhibiting strong emission lines in its optical spectrum, as noted in Carl K. Seyfert's seminal 1943 study of six spiral nebulae with bright, peculiar nuclei.[30] This classification as a Seyfert galaxy stems from the presence of narrow emission lines produced by ionized gas in the nuclear region, characteristic of Seyfert II types, though later observations refined it to Seyfert 1.9 due to faint broad-line components. These spectral features indicate photoionization by a central active galactic nucleus (AGN), with forbidden lines like [O III] dominating and ratios such as [O III] λ5007/Hβ ≈ 10 confirming the Seyfert nature.[31] A distinctive feature of Messier 106's AGN is the presence of water vapor megamasers in a thin, edge-on Keplerian disk orbiting the central supermassive black hole, discovered through 22 GHz radio observations. These masers, arising from ortho-H₂O transitions, trace the disk's rotation with high precision, revealing systemic, high-velocity, and low-velocity components that enable accurate measurements of the black hole mass (approximately 3.9 × 10⁷ M⊙) and the galaxy's distance (7.6 Mpc). The maser emission provides a unique probe of the sub-parsec-scale environment, unaffected by dust obscuration that plagues optical studies. The nucleus also displays X-ray variability on timescales of days to years, attributed to instabilities in the accretion disk, with observations from missions like XMM-Newton showing flux changes by factors of up to 100% in the 2-10 keV band. Accompanying this is a compact radio continuum source, likely from a jet or synchrotron emission linked to the accreting black hole, while the bolometric luminosity of the AGN is approximately erg s, marking it as a low-luminosity active nucleus. Recent James Webb Space Telescope (JWST) NIRCam imaging from 2024 has further illuminated the nuclear region, identifying the active nucleus through diffraction artifacts and providing enhanced views of AGN-driven shocks in the surrounding medium.[20] Compared to typical Seyfert galaxies, which often have luminosities exceeding erg s, Messier 106 appears brighter in resolved studies due to its relative proximity, facilitating high-resolution multiwavelength observations that reveal details elusive in more distant counterparts.[6] This accessibility has made it a benchmark for understanding low-luminosity AGNs and their feedback processes.[32]Extended Features and Dynamics
Anomalous Arms and Filaments
Messier 106 exhibits unusual extended structures known as anomalous arms, which deviate from the galaxy's primary spiral disk and are primarily composed of hot, ionized gas rather than stars. These arms were highlighted in ultraviolet and Hα imaging from the Hubble Space Telescope, released in 2013, where they appear as faint, arching features of glowing hydrogen emission extending outward from the nucleus.[33] Unlike the main arms, these structures appear to arch out of the disk plane in projection due to the galaxy's moderate inclination, spanning up to approximately 6 kpc (about 20,000 light-years) from the nucleus in Hα maps, with visible bifurcations and bending at distances of 5 kpc. Recent James Webb Space Telescope observations in 2024 have provided infrared views highlighting the dusty components and glowing regions along these arms.[4] Chandra X-ray Observatory data reveal these anomalous arms as diffuse emissions of hot gas, accompanied by filamentary plumes and bubbles likely ejected perpendicular to the disk. The X-ray spectra indicate thermal gas temperatures ranging from 0.37 to 0.6 keV, corresponding to roughly 4 to 7 million Kelvin, consistent with shocked interstellar medium heated by nuclear outflows.[34] These features include large bipolar bubbles extending about 8 kpc above and below the galactic plane, with interior dimensions of 4 by 3 kpc, encompassing diffuse plasma that spans up to tens of kiloparsecs overall. The hot gas filaments show enhanced X-ray emission aligned with radio jets, suggesting energetic disruption from the central active nucleus.[26] Radio and optical observations provide further evidence of shocked gas within these structures, with high [S II]/Hα ratios and elevated velocity dispersions up to 250 km s⁻¹ in the anomalous arms, indicating compression and heating from outflows.[6] These signatures contrast with the lower dispersions (30–50 km s⁻¹) in star-forming regions of the main disk, pointing to non-gravitational dynamics. Theories attribute the anomalous arms and filaments to superwinds or jet-driven shocks from the Seyfert nucleus's supermassive black hole, rather than tidal distortions from a major interaction.[34] This nuclear activity drives the ejection of gas into the halo, creating the observed perpendicular extensions.Star Formation and Stellar Populations
Messier 106 exhibits a moderate galaxy-wide star formation rate of approximately 3 solar masses per year, primarily traced through Hα emission from ionized gas in its spiral arms and circumnuclear regions.[6] This rate decreases significantly toward the central 3.4 kpc², where it drops to about 0.3 solar masses per year, reflecting limited gas availability in the inner disk amid active galactic nucleus feedback.[6] Far-infrared observations further support this distribution, linking the luminosity to dust-heated star-forming sites concentrated along the prominent spiral structure.[35] Young, massive stars dominate the H II regions within these arms, as revealed by ultraviolet imaging from the Hubble Space Telescope's Legacy Extragalactic UV Survey (LEGUS), which highlights bright knots of recent star formation.[36] These compact, blue sources, often aligned with Hα-bright areas, indicate ongoing bursts of high-mass stellar birth, with luminosities suggesting clusters of O- and B-type stars ionizing surrounding gas.[37] The galaxy's stellar demographics feature a diverse mix, including an old bulge population with ages spanning 8–12 billion years, as inferred from globular cluster spectroscopy and single stellar population models.[38] In contrast, the disk hosts a younger component with average ages around 5–8 billion years, alongside intermediate-age asymptotic giant branch and red giant branch stars, contributing to the overall stellar inventory estimated at roughly 400 billion stars.[39][40] Near the nucleus, a dust-obscured starburst contributes to the prominent infrared emissions detected by the Spitzer Space Telescope, where compact central sources reveal ongoing, obscured formation of stars amid dense interstellar material.[41] This region shows elevated mid-infrared flux, indicative of young stellar activity partially hidden by dust, though at a subdued rate compared to the outer arms.[42]Transient Events
Observed Supernovae
Messier 106 has hosted two confirmed supernovae, both of Type II, providing valuable data on stellar explosions in this nearby spiral galaxy. The first, SN 1981K, was discovered visually on November 3, 1981, by E. Hummel and P. Wild at an apparent magnitude of 17.[43] Classified as a Type II supernova, it was monitored in optical and radio wavelengths, revealing variability in radio flux density by up to 47% at 6 cm during observations. These radio data yielded an upper limit on the progenitor's mass-loss rate of approximately yr, indicating a less massive progenitor star compared to those of SN 1979C or SN 1980K. The second event, SN 2014bc, was a Type II-Plateau (II-P) supernova discovered by the Pan-STARRS1 3 survey on May 19, 2014 (MJD 56799.25), with the explosion dated to April 7.9 1.5, 2014.[44] It reached a peak apparent magnitude of approximately 14.6 in the band around 50 days post-explosion (uncorrected for negligible host reddening).[45] Extensively followed by professional facilities including the Liverpool Telescope in filters and the Gran Telescopio Canarias for spectroscopy at +52 and +102 days (showing Fe II velocity of 1460 100 km s), as well as amateur telescopes, SN 2014bc provided a detailed light curve spanning from pre-discovery detection on April 11 to late October 2014.[45] This supernova's photometry and spectra enabled application of the standardized candle method, yielding a distance estimate to Messier 106 of 7.08 0.86 Mpc, consistent with (though slightly lower than) the geometric maser distance of 7.6 0.23 Mpc and aiding refinement of Cepheid-based calibrations.[45] These events originated from massive stars in Messier 106's active star-forming regions along its spiral arms.Other Transients and Phenomena
In addition to supernovae, Messier 106 (NGC 4258) has hosted other optical transients, including a possible classical nova discovered in 2010. Designated NGC 4258OT2010-01, this event was detected by the Pan-STARRS1 Medium Deep Survey on May 15.3 UT at an apparent magnitude of , located in the vicinity of the galaxy's disk.[46] Subsequent analysis of its light curve from Palomar Transient Factory photometry indicated a rapid rise and decline consistent with nova characteristics, with brightness and shape comparable to the Galactic nova CP Pup, supporting its classification as an extragalactic nova rather than a failed supernova or other phenomenon.[47] X-ray observations have revealed several ultraluminous X-ray sources (ULXs) in Messier 106, which exhibit variability indicative of transient-like behavior. Archival XMM-Newton data identified multiple luminous point sources exceeding erg s, with at least four classified as ULXs based on their unabsorbed luminosities and positions off the nucleus. Specific examples include ULX X-3, with erg s, and ULX X-6, which displays spectral hardening and possible flux variations across observations spanning 2002–2015.[48][49] These sources, likely powered by intermediate-mass black hole accretion or super-Eddington stellar-mass black holes, show short-term variability on timescales of hours and long-term changes by factors of 2–5 over years, consistent with X-ray binary outbursts.[50][49] The active nucleus of Messier 106 also produces transient X-ray phenomena through flares, modeled as emissions from orbiting hotspots in the inner accretion disk. High-inclination XMM-Newton and Suzaku observations reveal rapid flux doubling on timescales of ~10^4 seconds, attributed to Doppler boosting from Keplerian motion near the central supermassive black hole.[51] These flares, recurring on months-to-years intervals, highlight the dynamic nature of the low-luminosity active galactic nucleus, with power spectral densities differing from higher-luminosity Seyferts and resembling low/hard-state X-ray binaries. No confirmed gamma-ray or radio transients beyond the persistent jet have been reported, though the galaxy's proximity continues to enable detailed monitoring for future events.[51]References
- https://science.[nasa](/page/NASA).gov/mission/hubble/science/explore-the-night-sky/hubble-messier-catalog/messier-106/