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Hercules A
Visible light image obtained by Hubble superposed with a radio image taken by the VLA.
Observation data (J2000 epoch)
ConstellationHercules
Right ascension16h 51m 08.1s[1]
Declination+04° 59′ 34″[1]
Redshift0.155000±0.000880[2][1]
Heliocentric radial velocity46,468±264 km/s[1]
Galactocentric velocity46,558±264 km/s[3][1]
Distance2,258 ± 158.5 Mly (692.4 ± 48.6 Mpc)h−1
0.6774
(Comoving)[1]
2,006 Mly (615.0 Mpc)h−1
0.6774
(Light-travel)
Apparent magnitude (V)16.6[1]
Apparent magnitude (B)18.1[1]
Characteristics
TypeWLRG; NLRG ELEG[1]
Size459,820 ly × 285,090 ly
(140.98 kpc × 87.41 kpc)
(diameter; "total" magnitude)[1][a]
164,200 ly × 164,200 ly
(50.35 kpc × 50.35 kpc)
(diameter; Very low surface brightness)[1][a]
Apparent size (V)0.25′ × 0.25′[1]
Other designations
Herc A, 3C 348, PGC 59117, 4C +05.66, MCG +01-43-006, NRAO 0518

Hercules A, or 3C 348, is a bright astronomical radio source galaxy in the constellation Hercules.[4][5] It is an elliptical galaxy, and the origin of one of the largest known astronomical radio sources, emanating 459,820 light years on either side of its point of origin, making the feature nearly a million light years across. Hercules A was first catalogued by astronomers at the University of Cambridge in April 1961 in a paper published to The Observatory.[6]

Observation

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During a survey of bright radio sources in the mid-20th century, astronomers found a very bright radio source in the constellation Hercules corresponding to an elliptical galaxy. Its strength in the middle range frequency and emission of synchrotron radiation suggested the source of radio emission may be undergoing a gravitational interaction.[7]

In April 1961, astronomers from the Radio Astronomy Group, later the Cavendish Astrophysics Group, detected the radio source[6] using the Cambridge Interferometer of the Mullard Radio Astronomy Observatory at Cambridge University in the United Kingdom, including it in the Third Cambridge Catalogue of Radio Sources (3C) as 3C 348, the 348th object detected by the survey.[8]

Characteristics

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Galaxy

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The galaxy, 3C 348, is a supergiant elliptical galaxy.[9][10] It is located inside a poor galaxy cluster with an X-ray luminosity of Lbol = 4.8 × 1037 W.[7] 3C 348 is classified as type E3 to E4 of the updated Hubble–de Vaucouleurs extended galaxy morphological classification scheme. It has a companion galaxy, shown appearing as a secondary nucleus, indicating it is merging.[11][12]

3C 348, the galaxy located in the center of the image, appears to be a relatively normal elliptical galaxy in visible light. When imaged in radio waves, however, plasma jets over one million light years long appear. Detailed analyses indicate that the galaxy is actually over 1,000 times more massive (approx. 1015 M) than our Milky Way Galaxy, and the central black hole is nearly 1,000 times more massive (approx. 4 billion M) than the black hole at our Milky Way's center, one of the largest known. The physics that creates the jets is poorly understood, with a likely energy source being matter ejected perpendicular to the accretion disc of the central black hole[13] which has grown more than 1.7×108 M, large enough to produce a shock front in the cluster's interstellar medium.[14][15]

Radio source

[edit]

The radio source in 3C 348 is considered powerful.[16] It is double-lobed with striking bizarre features such as a double optical core and radio intensity rings clustered together inside one of the host galaxy's two radio lobes. Despite not being a Fanaroff-Riley Class II neither an FR I source, it instead shows similarities to both types.[17][18]

See also

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Notes

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Hercules A

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from Grokipedia
Hercules A, also known as 3C 348, is an elliptical radio galaxy and active galactic nucleus (AGN) located in the constellation Hercules at a redshift of z = 0.154, corresponding to a distance of approximately 2 billion light-years from Earth.[1][2] It is one of the brightest extragalactic radio sources in the sky, emitting nearly a billion times more power in radio wavelengths than the Sun, with a flux density of about 45 Jy at 1.4 GHz.[1][2] The galaxy serves as the central dominant (cD) member of a cluster and harbors a supermassive black hole with a mass of approximately 4 billion solar masses, which is roughly 1,000 times more massive than the Milky Way's central black hole and powers the galaxy's intense activity.[1][3] The overall galaxy is approximately 1,000 times more massive than the Milky Way.[1] Hercules A's radio structure is particularly striking, featuring two vast lobes extending over 1.5 million light-years across, with the entire source spanning about 530 by 170 kiloparsecs (190 by 60 arcseconds) on the sky.[1][2][4] These lobes are connected to the core by relativistic jets, classified as an intermediate Fanaroff-Riley type I/II source, where the eastern jet is inclined about 50° toward Earth and the western jet recedes.[2] The western lobe exhibits three prominent ring-like structures at distances of 55–230 kpc from the host galaxy, interpreted as remnants of intermittent AGN outbursts that show spectral steepening with increasing distance.[2] Surrounding the galaxy is a hot X-ray-emitting gas cloud, visible in multi-wavelength observations that combine radio, optical, and X-ray data to reveal the interplay between the black hole's energy output and the intracluster medium.[1] First identified as a powerful radio source in the 1950s during early radio surveys, Hercules A was cataloged in the Third Cambridge Catalogue (3C) in 1959 and later optically confirmed as a single elliptical galaxy, dispelling earlier suggestions of a double-galaxy system.[4] Detailed imaging from telescopes like the Hubble Space Telescope and the Very Large Array has since highlighted its complex morphology, making it a key subject for studying AGN feedback and jet propagation in galaxy clusters.[1][4]

Discovery and Identification

Radio Detection

In the mid-20th century, pioneering radio astronomy surveys began systematically mapping the sky at meter wavelengths, uncovering a population of powerful extragalactic radio sources. The Third Cambridge Catalogue (3C), published in 1959 by the Cambridge University Radio Astronomy Group, represented a major advance, compiling data from observations at 159 MHz using the Cambridge one-mile radio telescope and a four-element interferometer to detect 471 sources above a flux limit of approximately 18 Jy north of declination -40°. Hercules A was first detected and cataloged as 3C 348 during this survey, marking it as one of the brightest radio sources in the sky with an integrated flux density of about 36 Jy at 159 MHz. The Cambridge Interferometer provided the initial position and confirmed the source's extended nature, classifying it as a double-lobed structure typical of early identified radio galaxies. Subsequent refinements in the revised Third Cambridge Catalogue (3CR) by Bennett in 1962, based on higher-resolution observations at 178 MHz, adjusted the flux density to 25.6 Jy and estimated the angular size as roughly 12 arcminutes by 2 arcminutes, highlighting its large-scale extent. The emission arises from synchrotron radiation by relativistic electrons in magnetic fields, with the spectrum exhibiting a power-law form that peaks in the middle radio frequencies around 100-1000 MHz due to the typical energy distribution of the electrons. The initial position determined from these radio measurements was right ascension 16h 51m 06s, declination +04° 59' (equinox B1950), corresponding closely to modern coordinates of RA 16h 51m 08.1s, Dec +04° 59′ 34″ (J2000). This radio detection laid the groundwork for later optical confirmation of the host galaxy.

Optical Confirmation

The optical identification of the radio source Hercules A, cataloged as 3C 348, occurred in the early 1960s as part of efforts to associate radio detections with visible counterparts. In 1961, P. J. S. Williams, D. W. Dewhirst, and P. R. R. Leslie proposed the association with a bright supergiant elliptical galaxy at right ascension 16h 51m 08.42s and declination +04° 59' 33.4" (J2000), based on positional overlap within the radio error box derived from Cambridge interferometer measurements and photographic plates from the Palomar Sky Survey.[5] These early plates revealed the galaxy's extended, smooth envelope characteristic of a massive elliptical, with an integrated apparent magnitude of approximately V = 14.26 and B = 14.35, making it one of the brighter extragalactic radio sources optically. The galaxy is formally designated PGC 59117 in the Principal Galaxies Catalogue and commonly referred to as Herc A in astronomical literature. Spectroscopic observations provided definitive confirmation of the identification and distance. In 1965, Allan Sandage obtained spectra using the 200-inch Hale telescope, identifying absorption lines from Ca II H and K, G band, and other features shifted by z = 0.155, yielding a radial velocity of 46,468 ± 264 km/s relative to the solar neighborhood after correction for the Sun's motion. This redshift placed Hercules A at a cosmological distance, with estimates ranging from 615 to 692 Mpc (2,006 to 2,258 million light-years) based on Hubble constant values between 70 and 75 km/s/Mpc and standard ΛCDM cosmology. The spectra showed a typical early-type galaxy continuum with no strong emission lines, consistent with the host of a radio-loud active nucleus. Early photographic and spectroscopic studies also highlighted morphological peculiarities suggestive of dynamical activity. As early as 1957, Rudolf Minkowski noted on plates from the National Geographic Society-Palomar Observatory Sky Survey that the galaxy appeared as a peculiar double system, with a fainter companion offset by about 5 arcseconds to the northwest, interpreted as evidence of an ongoing merger between the primary elliptical and a smaller satellite galaxy. This feature was corroborated in the 1961 identification work, where the companion contributed to the asymmetric envelope visible on red-sensitive plates, providing initial clues to the galaxy's evolutionary history without resolving finer details like dust lanes or tidal tails.[5]

Observational History

Early Surveys

Following its initial detection as 3C 348 in the Third Cambridge Catalogue of Radio Sources in 1959, Hercules A became a target for follow-up radio observations in the 1960s using early interferometers, such as those at the California Institute of Technology Radio Observatory. These measurements resolved the source into a double-lobed structure, with the two lobes separated by approximately 200 arcseconds and aligned symmetrically on either side of the central position. Interferometric visibility functions indicated that the emission was dominated by extended components rather than a compact core, establishing the basic extent of the radio structure spanning several arcminutes on the sky.[6] Early spectral measurements across frequencies from 178 MHz to 5 GHz revealed a power-law spectrum with a spectral index of approximately -0.8, consistent with synchrotron emission from relativistic electrons in magnetic fields. Radio luminosity estimates at 1 GHz placed the total output at around 10^{26} W Hz^{-1}, classifying Hercules A as one of the most luminous extragalactic radio sources known at the time and highlighting its status as a powerful radio galaxy. These properties were derived from flux density ratios relative to calibration sources like Cygnus A, confirming the non-thermal nature of the emission without evidence of significant spectral curvature at low frequencies. Optical surveys in the early 1960s, including deep plates from the Palomar Observatory, confirmed the radio position's coincidence with a bright elliptical galaxy of magnitude ~15.5 exhibiting peculiar emission-line features and a faint surrounding cluster of galaxies. The host galaxy's redshift of z = 0.154, measured spectroscopically, indicated a distance of roughly 600 Mpc (using contemporary cosmology), placing Hercules A in a poor cluster environment with fewer than 20 member galaxies within the Abell radius. Initial notes on the alignment suggested that the radio axis was roughly perpendicular to the galaxy's major optical axis, hinting at possible dynamical interactions, though detailed morphology awaited higher-resolution imaging. Distance refinements in the 1970s, incorporating improved Hubble constant estimates, adjusted the luminosity distance to about 800 Mpc, refining the inferred physical size of the lobes to over 1 Mpc.

Modern Multi-Wavelength Imaging

In 2012, the Hubble Space Telescope captured high-resolution visible-light images of Hercules A (3C 348), revealing intricate plasma jets extending approximately 1.5 million light-years from the galaxy's core. These observations, taken using the Wide Field Camera 3 instrument, showcased the jets as glowing filaments of hot gas and plasma, providing unprecedented detail on their structure and curvature as they propagate outward.[1] Complementary radio observations with the Karl G. Jansky Very Large Array (VLA) have depicted the enormous radio lobes of Hercules A, which span about 3 arcminutes across the sky and vastly dwarf the optical extent of the host galaxy. These VLA images, obtained at frequencies between 4 and 9 GHz, highlight the lobes' complex morphology, including ring-like features and sharp edges, with resolutions down to arcsecond scales that resolve fine-scale emissions invisible at optical wavelengths.[7] A notable 2012 NASA release combined these HST visible data with VLA radio observations into multi-wavelength composites, vividly illustrating the misalignment between the plasma jets and the host galaxy's major axis, where the jets bend dramatically away from the galaxy's elongated structure. This juxtaposition underscores the dynamic interplay between the jets and the surrounding environment.[8] Post-2010 follow-up observations, including sub-arcsecond resolution images from the International LOFAR Telescope at 144 MHz in 2022, have further refined measurements of jet lengths and revealed enhanced details in the optical core and lobe rings, confirming the jets' extent and providing insights into low-frequency emission variations. Ground-based and space-based efforts, such as additional VLA configurations, continue to sharpen these features, building on earlier baselines for more precise structural mapping.[2]

Physical Properties

Host Galaxy Morphology

The host galaxy of Hercules A, designated 3C 348, is a supergiant central dominant (cD) elliptical galaxy situated at the center of a poor galaxy cluster known as the Hercules A cluster, where it serves as the brightest and most massive member.[9][10] This classification reflects its extended envelope typical of cD galaxies, which are among the most luminous and massive ellipticals in clusters, with an elongated structure indicating an E/S0 morphological type.[11] The galaxy's total mass is approximately 1000 times that of the Milky Way, amounting to roughly 1015M10^{15} M_\odot.[1] Recent X-ray observations (as of 2025) have identified cocoon shocks and X-ray cavities, highlighting interactions with the surrounding intracluster medium.[12] Optical imaging reveals clear evidence of an ongoing merger with a companion galaxy of comparable luminosity, manifesting as a double optical core and prominent tidal features.[11][13] Hubble Space Telescope observations in U, V, and I bands disclose a complex network of dusty filaments spanning about 10 arcseconds (equivalent to ~26 kpc at the galaxy's distance), interpreted as gas stripped during the merger encounter with a secondary nucleus possibly from an S0 galaxy.[14] These features underscore the dynamical interaction shaping the galaxy's structure. In terms of size and luminosity, 3C 348 exhibits a low surface brightness with an apparent V-band magnitude of 16.36, translating to an absolute magnitude of approximately -22.8 given its redshift of z=0.154z = 0.154 (corresponding to a luminosity distance of about 700 Mpc). The effective radius encompasses a vast stellar extent, consistent with its supergiant status, while the stellar population is dominated by old stars typical of massive ellipticals, potentially augmented by recent star formation episodes linked to the merger, as evidenced by faint blue continuum emission extending ~8 kpc.[14]

Central Supermassive Black Hole

The central supermassive black hole (SMBH) in Hercules A powers its exceptional radio activity as an active galactic nucleus (AGN). Estimates place the SMBH mass at approximately 2.5 × 10⁹ M⊙, derived from correlations between black hole mass and host galaxy bulge luminosity, as well as jet power scaling relations that link mechanical output to central engine properties.[15] These methods account for the galaxy's high stellar mass and the observed jet energetics, providing indirect constraints since direct dynamical measurements, such as stellar or gas kinematics, remain challenging at the distance of Hercules A (z ≈ 0.154). The SMBH is actively accreting material through a surrounding disk, characteristic of a luminous AGN, with evidence pointing to fueling by gas inflows triggered by a recent merger in the host galaxy. Hubble Space Telescope imaging reveals dusty filaments and a double optical core in the elliptical host, indicative of merger remnants that drive cold gas toward the nucleus, sustaining the accretion at rates sufficient for the observed output.[16] This merger-induced inflow likely provides the raw material for the disk, where viscous processes heat and radiate as the gas spirals inward, though the exact disk structure—potentially a standard Shakura-Sunyaev geometrically thin, optically thick accretion flow—remains inferred from the AGN's spectral energy distribution rather than resolved observations. Relativistic jets are launched from the vicinity of the SMBH, likely via the Blandford-Znajek mechanism involving magnetic fields threading the event horizon and extracting rotational energy from the spinning black hole. These jets achieve bulk Lorentz factors of several, corresponding to speeds approaching 0.99c, as evidenced by synchrotron emission properties and apparent superluminal motion limits in high-resolution radio maps. The jets align closely with the host galaxy's minor axis, consistent with simulations showing that merger torques or binary black hole dynamics can orient the angular momentum along this axis, facilitating collimated ejection perpendicular to the galactic disk.[17][18] The energy output from the central engine manifests in a total radio luminosity of approximately 10⁴⁴ erg s⁻¹, dominated by synchrotron radiation from relativistic electrons in the jets and lobes, with jet mechanical power estimates around 10⁴⁴–10⁴⁶ erg s⁻¹ derived from X-ray cavity energetics. This luminosity underscores Hercules A's classification as a Fanaroff-Riley II radio galaxy, where the high power sustains extended structures over megaparsec scales.[15]

Emission Features

Radio Lobes and Jets

Hercules A displays a prominent double-lobed radio morphology, characterized by extended structures featuring concentric ring-like features and regions of enhanced emission interpreted as hotspots, originating from relativistic jets launched by the central supermassive black hole. These lobes span approximately 1.5 million light-years, dwarfing the host galaxy and encompassing much of the surrounding galaxy cluster environment.[1][19] The radio emission in the lobes and jets arises primarily from synchrotron radiation, generated by relativistic electrons gyrating in ordered magnetic fields estimated at around 12 μG within the lobes. Polarization measurements reveal that these magnetic fields are predominantly aligned along the boundaries of the lobes and the jet axes, with fractional polarization reaching up to 20-30% in the jets, indicating a structured field configuration amid turbulent components. The spectral index of the lobes is typically steep, around α ≈ -1.2, reflecting synchrotron energy losses and aging of the electron population, while the rings and inner jet regions exhibit flatter spectra (α ≈ -0.7 to -1.0), consistent with more recent particle injection episodes.[20][21][22] The jets extend over hundreds of kiloparsecs, with initial widths of a few kiloparsecs near the core expanding to tens of kiloparsecs at larger distances, and display a notable misalignment of approximately 35° between parsec-scale and kiloparsec-scale components, along with wiggling patterns attributed to hydrodynamic instabilities. This asymmetry and curvature suggest possible jet precession driven by instabilities such as the helical kink mode. Due to the presence of bright, extended lobes without compact terminal hotspots and an intermediate edge-brightened appearance, Hercules A defies strict classification as an FR I or FR II radio galaxy, instead exhibiting hybrid morphological traits.[19][23][24]

X-ray Cavities and Inverse Compton Emission

Chandra X-ray observations of Hercules A have revealed a bolometric luminosity of 4.8 × 10³⁷ W within the 0.5–7 keV band, highlighting the system's energetic activity. These observations detect prominent X-ray cavities, interpreted as regions where thermal gas has been displaced by expanding radio lobes, creating deficits in surface brightness. Two primary cavities are identified: a northeastern one with dimensions of approximately 90 × 80 × 100 kpc and a southwestern one with dimensions of about 160 × 120 × 110 kpc, each with radii around 50 kpc and located 65–70 kpc from the cluster center.[20] These cavities provide evidence of the mechanical feedback from the central active galactic nucleus, with their volumes indicating significant energy injection into the intracluster medium. A detailed 2025 analysis of Chandra data uncovers a cocoon shock structure resulting from the jet expansion, manifesting as edges in the X-ray emission. The shock exhibits an elongated morphology, with radii of approximately 150 kpc along the north-south axis and 280 kpc along the east-west axis.[20] Temperature jumps across the shock are measured at 1.42 ± 0.11 in the north-south direction and between 1.35 and 1.65 in the east-west sectors, corresponding to Mach numbers of 1.65 ± 0.05 and up to 1.9 ± 0.3, respectively. These features signify supersonic expansion of the radio cocoon, driving heating and turbulence in the surrounding gas.[20] Extended inverse Compton emission is detected in the X-ray regime from the radio lobes, arising from relativistic electrons upscattering cosmic microwave background photons to X-ray energies. This non-thermal emission is characterized by a flux density of 21.7 ± 1.4 (stat) ± 1.3 (sys) nJy at 1 keV, favoring an inverse Compton origin over thermal models due to the low electron densities (around 3 × 10^{-3} cm^{-3}) in the lobes. The eastern jet's X-ray emission supports particle acceleration mechanisms, potentially involving Doppler boosting with a factor of ~2.7 or synchrotron processes requiring electron Lorentz factors γ ≥ 10^8.[20] Implications include equipartition energy densities, with magnetic fields of ~12 ± 3 μG in the lobes and relativistic electron pressures of ~3.6 ± 1.2 × 10^{-11} erg cm^{-3}, comparable to or exceeding the thermal intracluster medium pressure by a factor of 1.5–2. These findings underscore efficient in-situ acceleration of particles within the cavities, sustaining high-energy processes over large scales.

Astrophysical Context

Galaxy Cluster Environment

Hercules A, also known as 3C 348, is the brightest and central dominant galaxy in the poor galaxy cluster designated as the Hercules A cluster.[20] This cluster hosts a sparse population of member galaxies, with 3C 348 serving as the brightest cluster galaxy (BCG) at its core. The cluster's intracluster medium (ICM) exhibits a bolometric X-ray luminosity of approximately 5×10445 \times 10^{44} erg s1^{-1}, indicative of a relatively low-mass system compared to richer clusters.[20] The ICM consists of a hot, X-ray emitting gas halo with temperatures ranging from 4.1 to 7.74 keV, varying spatially across the cluster.[20] This gas extends over approximately 640 kpc across at the cluster's redshift of z=0.154z = 0.154, confirming its cohesion through the coherent thermal structure observed in X-ray imaging.[20] The central electron density of the ICM is approximately 8×1038 \times 10^{-3} cm3^{-3}, typical for a poor cluster environment.[25] The total cluster mass is estimated to range from 2×10142 \times 10^{14} to 2×10152 \times 10^{15} MM_\odot, reflecting uncertainties in modeling the gravitational potential from available X-ray and optical data.[26] Spatial variations in ICM temperature and density profiles are evident, associated with AGN activity.[20] The redshift places the cluster at a luminosity distance of approximately 700 Mpc, with the extended X-ray emission providing key confirmation of its bound, cohesive nature.[20]

Jet Feedback Mechanisms

The jets of Hercules A inject enormous amounts of energy into the surrounding intracluster medium (ICM), primarily through shocks and the displacement of hot gas, leading to significant heating that offsets radiative cooling losses by a factor of approximately 100.[27] This mechanical feedback process raises the temperature of the ICM, preventing excessive gas cooling and thereby suppressing star formation across the cluster environment.[27] Observations indicate that the total energy budget of the outburst is around 3 × 10^{61} erg, delivered over an estimated duration of about 60 million years with a mean jet power of roughly 1.6 × 10^{46} erg s^{-1}.[27] Feedback models for Hercules A incorporate an outburst history characterized by intermittent AGN activity, with evidence for multiple episodes including a major event approximately 60 million years ago followed by a restart around 20 million years ago.[2] These recurrent outbursts, inferred from ring-like structures and spectral aging in the radio lobes, suggest episodic energy injection that sustains long-term ICM heating.[2] X-ray cavities provide direct evidence of this energy displacement, where buoyant bubbles rise and further distribute heat.[27] In the broader context of galaxy evolution, the jet feedback in Hercules A plays a crucial role by regulating cooling flows in the cluster core, maintaining thermal balance and quenching potential starbursts that could otherwise arise from gas inflows or mergers.[27] This process contributes to the overall suppression of star formation in massive ellipticals and their satellite systems, aligning with models where AGN outbursts prevent excessive growth in cluster-dominant galaxies.[28] On larger scales, such feedback connects to astrophysical relations where jet power scales with supermassive black hole mass as $ P_{\rm jet} \propto M_{\rm BH}^{1.5} $, highlighting the efficiency of energy extraction in powerful radio galaxies like Hercules A.

References

  1. A multi-wavelength view of radio galaxy Hercules A - ESA/Hubble
  2. Origin of the ring structures in Hercules A - Sub-arcsecond 144 MHz ...
  3. Hercules A - National Radio Astronomy Observatory
  4. The radio source Hercules A - NASA/ADS - Astrophysics Data System
  5. Brightness Distribution in Discrete Radio Sources.IV. a Discussion of ...
  6. VLA Radio Image of Hercules A (3C 348) - NASA Science
  7. https://science.nasa.gov/missions/hubble/a-multi-wavelength-view-of-radio-galaxy-hercules-a
  8. Hercules A (3C 348) - Constellation Guide
  9. The environment of Hercules A - ScienceDirect.com
  10. Optical/ultraviolet morphology and alignment of low-redshift radio ...
  11. The Optical Structure of the Radio Galaxy Hercules A - NASA ADS
  12. HUBBLE SPACE TELESCOPE OBSERVATIONS OF DUSTY ...
  13. [PDF] arXiv:1007.1227v2 [astro-ph.CO] 22 Nov 2010
  14. Hubble Space Telescope Observations of Dusty Filaments in ...
  15. Saxton, Bicknell, & Sutherland, Cocoon of Hercules A - IOP Science
  16. A multiband study of Hercules A – II. Multifrequency Very Large ...
  17. [PDF] and kpc-scale environment of the powerful radio galaxy Hercules A.
  18. Cocoon shock, X-ray cavities, and extended inverse Compton ...
  19. A multiband study of Hercules A. II. Multifrequency VLA imaging - arXiv
  20. Origin of the ring structures in Hercules A - Sub-arcsecond 144 MHz ...
  21. Jet/Lobe Transition, Wiggling, and the Magnetic Field Distribution
  22. On the large scale morphology of Hercules A: destabilized hot jets?
  23. and kpc-scale environment of the powerful radio galaxy Hercules A
  24. [PDF] SIBELIUS-DARK: a galaxy catalogue of the local volume from ... - HAL
  25. The Powerful Outburst in Hercules A - IOPscience
  26. INTRACLUSTER MEDIUM REHEATING BY RELATIVISTIC JETS
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