4C +26.42 is one of the powerful
radio galaxies inhabiting the center of the cluster.[4] Radio-loud,[5] low-luminous[6] and classified as a
Fanaroff-Riley class I, the galaxy contains a strong double-lobed
radio source,[7] that stretches ≈10 kpc on both sides of the nucleus region measuring P1.4 1025 W Hz-1[8] and found occupying inside the cluster flow.[9] It has a radial
velocity of 365 km s-1,[10] with a complex core structure,[11] and pole-on dispersion in diameter, indicating a marginal
intrinsic dispersion.[12] Furthermore, it is a
LINEAR galaxy, with an
emission spectrum characterized by broad weak ion
atoms.[13]
The galaxy is known have a pair of filaments, coiled together. Known as the "SE Filament", they are estimated to have a distance of ∼ 42′′ and 35′′ respectively but have unresolved
widths in Hα (< 0. ′′7 ∼ 1 kpc) with thin-looking appearances, reminding of
magnetic field lines.[14]
An structure has been discovered inside the envelope of 4C +26.42. Traced from a previous merger with another giant subcluster galaxy,[15] the structure has a
measurement of 400 kpc from the center which protrudes towards the north–south direction. When reached at the largest
radius, a low-surface brightness region is found, with a slight
angle pointing towards
east direction. According to researchers, the total I-band magnitude and envelope of the galaxy is -26.6, making 4C +26.42 among the brightest galaxies known.[16]
Nebula line emission
4C +26.42 contains a nebular
line emission found coruscating. With a luminosity range of L(Hα) ≈ 1042ergs s-1, within 20 kpc from the central galaxy, the line emission is embedded inside a filament extending towards the southern nucleus region by 80 kpc.[17] An excessive blue light is also found as well, which is probably emitted out from both young
stars in
globular clusters[18] and
massive star populations located inside the galaxy similar to Hydra A.[19]
Molecular outflows by radio bubbles
4C +26.42 is known to manifest robust
molecular 109 M⊙ gas flows, with
molecular gas positioned in a pair of filaments. With an estimated
length of ∼ 7 kpc, north and
south from the nucleus, the filaments are jutted around the outer edges of two inflated radio bubbles, caused by evaporation of
plasma through heated
radio jets launched by the galaxy.[20]
Results shows North filament is found flat and increased
velocity gradient that goes from the systemic velocity at the nucleus to a
maximum velocity of -370 km s-1. As for the South filament, it shows the opposite by having a shallow velocity gradient, practically collapsed through
starbursts. Through comparing both filaments together, they show a close bond specifying these filaments are indeed gas flows caused by the expansion of radio bubbles. Researchers concluded the total amount of molecular gas
mass is 3.2 ± 0.2 × 109 M⊙.[21]
Estimated star formation
The
star formation in 4C +26.42 are shown to vary, based on different observations. Several studies shows, the estimated star formation rate is said to be smaller than 1–20 M⊙ yr−1 based on different data and methods.[22][23] Based on ultraviolet
imaging, it is said to betwixt of 5 and 20 M⊙ yr−1. Deducing the initial mass function (IMF) as top-heavy with a
slope of 3.3 yields, researchers suggested the star formation in 4C +26.42 is extremely high, reaching star formation rates of 581 and 758 M⊙ yr−1.[24]
It was not until then researchers decided to calculated the actual star formation in 4C +26.42. Detecting
Lyman-alpha that is emitted from the galaxy,[25] they found it has a significant number of
O-type stars within luminosity ranges of 1500 Å, L1500 = 1.9 × 1042 ergs s-1. Applying new methods like Galactic extinction law,[26]extinction value (EB-V = 0.14)[27] and foreground screen dust modes, they predicted the increasement of O-type stars is 5.3 x 104. Accurately, the O-type stars is 2.4 × 104 based on a modern
spectroscopy method,[28] indicating the actual star formation rate is only within the compass of 8-23 M⊙ yr-1. Finally researchers used a star formation model corresponding to far-ultraviolet colors whom they found the star production rate in 4C +26.42 is 5-10 M yr-1 over the past 5 billion years.[29]
Radio morphology
According to
Very Long Baseline Array observations at 1.6, 5, 8.4 and 22 GHz, 4C +26.42 has a two-sided source, with a geometrical Z-structure located from the core region by ~5 mas.[30] The radio morphology is found on small-scale with core-power 5 GHz Log Pcore, 5GHz = 23.70 W/Hz and radio power results at 0.4 GHz Log Ptot, 0.4 GHz.[31]
Faraday rotational measure
The
faraday rotational measure in 4C +26.42 is extortionate. Exceeding 2000 rad m-2 when observed in high resolution (0.6 arcsec) VLA images, the radio source is found
polarized by 10% to 30%.[32] The magnitude and the scale comparable with a boiling (108) and thick (0.03 cm-3)
X-ray emitting gas. Based on the degree of ordering, the magnetic field field is within the ranges of 20 and 100 μG.[30]
^Ehlert, S.; McDonald, M.; Miller, E. D.; David, L. P.; Bautz, M. W. (2015-01-28). "A very deep Chandra observation of Abell 1795: The Cold Front and Cooling Wake". The Astrophysical Journal. 799 (2): 174.
arXiv:1406.4352.
doi:
10.1088/0004-637X/799/2/174.
ISSN1538-4357.
^Liuzzo, E.; Giovannini, G.; Giroletti, M. (2011-03-02), Nuclear properties of Brightest Cluster Galaxies: results and new observations for two peculiar cases,
arXiv:1103.0450