Revealing A Head-on Major Merger in the Nearby NGC 6338 Group with Chandra and VLA observations

By analyzing the Chandra archival data of the nearby NGC 6338 galaxy group, we identify two X-ray bright clumps (N-clump and S-clump) within the central 100 kpc, and detect an arc-like X-ray brightness discontinuity at the south boundary of the N-clump, which is defined as a cold front with a gas flow Mach number of M<0.8. Furthermore, at the north-east boundary of the S-clump (dominated by galaxy NGC 6338) another X-ray edge is detected that corresponds to a weaker cold front. Therefore, the two clumps are approaching each other approximately from opposite directions, and the group is undergoing a head-on collision that is in a stage of pre-core passage. This merger scenario is also supported by the study of the line-of-sight velocity distribution of the group member galaxies. The merger mass ratio is about 1:1.8 as estimated from the central gas temperature of the two clumps, which suggests the merger is most likely to be a major merger. We also analyze the VLA 1.4 and 4.9 GHz radio data, but we do not detect any extended radio emission that is associated with the merger.


INTRODUCTION
In the framework of hierarchical structure formation, galaxy clusters grow in size by merging with subunits, releasing as much as 10 64 erg of kinetic energy as thermal energy by driving shocks (Sarazin 2002), with each merger event typically lasting for about 2 − 5 Gyr (e.g., Roettiger et al. 1997;Ascasibar & Markevitch 2006). It is expected that major merger processes can generate remarkable hydrodynamic substructures in the intracluster medium (ICM), such as shocks and cold fronts that show arc-shaped or edge-like morphologies, corresponding to gas density and temperature jumps (e.g., Markevitch & Vikhlinin 2007, and references therein). These substructures can be used to determine the kinematics of the merger and to study the conditions and transport processes in the ICM, including electron-ion equilibrium and thermal conduction (e.g., Markevitch 2006).
It is likely that a fraction of the shock energy can be converted into the acceleration of relativistic particles (e.g., Blandford & Eichler 1987), and in cluster mergers this process could produce synchrotron radio emission (e.g., Feretti et al. 2012;Brunetti& Jones 2014). Giant radio halos and relics have been observed in galaxy clusters (e.g., Feretti & Giovannini 2008), and recent years, many more radio halos and/or relics in lower frequencies have been detected in relaxed clusters, even in poor clusters (e.g., Feretti et al. 2012), some of which have been explained by gas sloshing in the core (e.g., ZuHone et al. 2013). However, as radio emitting electrons have short radiative lifetimes (∼ 10 7 − 10 8 yr), it is difficult to explain the Mpc size of extended radio halos (for a review see Brunetti& Jones 2014). And there exists some dynamically disturbed clusters that do not show any evidence of radio halo, such as the well-known merging clusters A119 (Giovannini & Feretti 2000). Also, Cassano et al. (2010) found four such clusters: A141, A781 (that has been found to host a radio halo in Govoni et al. (2011), A2631 and MACS J2228.5+2036. On the scale of galaxy group, some possible signals for extend radio sources related to the intergalactic magnetic field have been found (e.g., Nikiel-Wroczyński et al. 2017), while the evidence for radio relics or halos in the groups is not yet conclusive. The above indicates that the formation mechanism of radio halos is currently not fully understood.
As we know, a large fraction of the baryons in the nearby Universe resides in galaxy groups with X-ray luminosities ∼ 10 41 − 10 43 erg s −1 and gas temperature ∼ 0.3 − 2 keV (e.g., Ponman & Bertram 1993;Mulchaey 2000). Galaxy groups are much more representative gravitational systems than rarer rich clusters of galaxies (e.g., Geller & Huchra 1983;Tully 1987) and important for understanding the gravitational and thermal evolution of most of the matter in the Universe. The effects of non-gravitational heating, such as AGN feedback and merger shocks, are expected to be more significant in lower mass systems as the energy input from these sources is comparable to the binding energy of the group (e.g., Ponman et al. 1996Ponman et al. , 1999Helsdon et al. 2000). Major and minor group mergers, and their subsequent relaxation, govern the formation of the largest scale structures and can have a considerable impact on their constituent galaxies. However, studies of galaxy group mergers have been limited due to their faint X-ray emission and low galaxy densities. And there are not many research works focused on group mergers (e.g., Kraft et al. 2006Kraft et al. , 2011Machacek et al. 2010Machacek et al. , 2011Russell et al. 2014;Schellenberger et al. 2017) when compared with a large number of studies on galaxy cluster mergers.
In this paper, we present a nearly head-on merger discovered in the Chandra observation of the nearby NGC 6338 galaxy group (z = 0.02824; Wegner et al. 1999). The brightest galaxy NGC 6338 (cD, S0, M B = 13.6; z = 0.02743) and the member galaxy 2MASX J17152326+5725585 (hereafter 2MASX J1715; E0, M B = 15.4; z = 0.03212; Smith et al. 2004) present some evidence of galaxy-galaxy interaction in the optical band, as shown on the SDSS image (Fig. 1a). Both NGC 6338 and 2MASX J1715 (located north about 1.3 ′ from NGC 6338) are elongated in the north-south direction; In particular, the latter contains a double nucleus (Berlind et al. 2006, Fig. 1a), and has an asymmetrical optical morphology that are possibly due to tidal forces. In the VLA NVSS map (Condon et al. 1998, Fig. 1a), a point-like radio source is shown at the center of galaxy NGC 6338, as reported by Dong et al. (2010) and Pandge et al. (2012). We also find an extended radio emission located in the south-east side of the group, which infers that the group has a radio relic.
In §2, we describe the Chandra and VLA observations, and data reductions. In §3, we present the X-ray image and VLA radio map. In §4, we analyze the velocity distribution of the identified member galaxies. In §5, we discuss and summarize our results. Throughout the paper, we adopt the cosmological parameters H 0 = 73 km s −1 Mpc −1 , Ω b = 0.044, Ω M = 0.27, and Ω Λ = 0.73. Unless stated otherwise, the quoted errors stand for 90% confidence limits.

Chandra
The NGC 6338 galaxy group was observed by Chandra on September 17-18, 2003 (47.94 ks, ObsID 4194) with chips 0, 1, 2, 3, 6 and 7 of the Advanced CCD Imaging Spectrometer (ACIS) operating in VFAINT mode. We use the Chandra data analysis package CIAO version 4.4 and CALDB version 4.5.1 to process the data, by starting with the level-1 raw event files in order to apply the latest corrections for the charge transfer inefficiency (CTI) to improve the energy resolution of the CCDs and to remove most of the effects of the apparent gain shift. We keep events with ASCA grades 0, 2, 3, 4, and 6, and removed all the bad pixels, bad columns, and columns adjacent to bad columns and node boundaries. We examine the 0.3 − 12.0 keV lightcurves extracted from the background regions defined on the four ACIS-I chips, and find that there are almost no strong background flares that increased the background count rate to > 115% of the mean quiescent value. The obtained net exposure is 47.13 ks.
For the spectral analysis, we extract the Chandra spectra in the 0.7-7.0 keV band. Background spectra are extracted from the Chandra blank-sky fields; a cross-check based on the use of local background yields essentially the same result.

VLA
We use the radio data of the NGC 6338 group observed with the Very Large Array (VLA) on 1998 July 28 at the frequency of 1.4 GHz (L-band) in B-array (AP3690) and on 1997 June 27 at the frequency of 4.9 GHz (C-band) in C-array (AE0110).
The observations were carried out with 50 MHz bandwidth for the total integration time of 950 seconds and 630 seconds for L-band and C-band, respectively. In these observations 3C 48 is used as the primary flux density calibrator, while 3C 343 and 1739+522 are used to determine the complex antenna gains, respectively. The NRAO achieved data is analyzed in AIPS 7 (version 31DEC16) using the standard procedures. Self-calibration is applied to remove residual phase variations. The final images are produced by AIPS task IMAGR.

X-ray Image
In Figure 1b, we show the ACIS-I image of the central 200 kpc × 200 kpc (5.8 ′ × 5.8 ′ ) region of the NGC 6338 group in the 0.3−5.0 keV band, which has been corrected for exposure but not for background. Two X-ray bright clumps are clearly visible in the center region with a projected separation of about 48h −1 73 kpc (83 ′′ ; 1 arcsec=0.575 h −1 73 kpc at the redshift of z = 0.02824). The X-ray peak of the south clump (hereafter S-clump) is consistent with the optical centroid of NGC 6338 within 3 ′′ , and the X-ray peak of the north clump (hereafter N-clump) is found at 2.8h −1 73 kpc (5 ′′ ) north of member galaxy 2MASX J1715. In Figure 1b, two arcshaped edges can be seen at the south boundary of N-clump (hereafter N-edge) and the north-east boundary of S-clump (hereafter S-edge); and two X-ray stripped tails also are found located roughly north of N-clump and south-west of S-clump, respectively. These above findings indicate that two clumps are approaching each other approximately from opposite directions, and the group is undergoing a nearly head-on merger.
To study the edges in a quantitative way, we extract the exposure-corrected X-ray surface brightness profiles (SBPs; Fig. 2a and 2b) in the 0.3 − 2.0 keV band using two sets of semi-annuli, which are defined in two semi-circles as shown in Figure 1b. We find that both profiles show clear surface brightness discontinuities at the edges; across the N-edge, the surface brightness increases inward by a factor of 2.1 within 3.6h −1 73 kpc (6.3 ′′ ), and across the S-edge, it increases by a factor of 1.6 within 6.4h −1 73 kpc (11.1 ′′ ). Surface brightness discontinuities appear usually due to the jumps in gas density accompanied with temperature jumps, and often indicate the existence of shocks as in 1E 0657−56 (Markevitch et al. 2002) and Abell 520 , or cold fronts as in Abell 1795  and Abell 168 (Hallman & Markevitch 2004).

Temperature and Metal Abundance Distributions
In order to investigate the thermal properties of the head-on merging group, we obtain the two-dimensional gas temperature and metal abundance distributions (Table 1) by extracting spectra from the regions including the semi-annuli of two clumps (North semi-annuli of N-clump, hereafter NN; South semi-annuli of N-clump, SN; North-east semi-annuli of Sclump, NS; and South-west semi-annuli of S-clump, SS) and Box (a-l) as shown in Figure 3. We fit each spectrum with an absorbed APEC model coded in the XSPEC v12.4.0 software by fixing the redshift and absorption to z = 0.02824 and the Galactic value N H = 2.23 × 10 20 cm −2 (LAB Survey of Galactic HI, Kalberla et al. 2005), respectively. Allowing the redshift to vary does not improve the fits. Except for the spectrum extracted in the north middle semi-annulus of S-clump (Region NS2), no more than Galactic absorption is needed.
In the central region, each of two clumps has a cool core with the gas temperature of 1.0 − 1.3 keV for N-clump and 1.3 − 1.5 keV for S-clump. The gas temperatures between two clumps (Region SN2 and NS3) are up to 3.9 keV, which are significantly higher than those of Regions NN2 and SS3 (2.0 − 2.6 keV). With the two clumps approaching each other, the gas between two clumps is compressed, and it is most likely heated by shocks generated in the merger. In the surroundings, the gas temperatures of Boxes (a), (e), (f), and (i) with the value of 3.2 − 4.0 keV are significantly higher than those of Boxes (c) (d), (g), (h), (k), and (l) with the value of 1.9 − 2.5 keV. The above four high-temperature boxes are on either sides of the central merger region, the gas of which is probably the hot gas expelled from the collision axis areas in the merger process, as shown in simulation works (e.g., Ricker et al. 2001).
The stripped gas of the S-clump [Boxes (g), (k) and (l)] has a higher metal abundance in a range of 0.5 − 1.5 Z ⊙ (Table 1), comparing with the average metal abundance of 0.25 +0.08 −0.05 Z ⊙ (Rasmussen & Ponman 2007). In the tail of N-clump [Boxes (c) and (d)] no enhanced metal abundance is found.

Two Cold Fronts
We show the gas temperature profiles across the N-edge and S-edge in Figure 2(c − d). After correction for projection effects (Table 1), we find that the gas temperatures outside both of the edges (4.0 +1.0 −0.7 keV and 3.6 +0.5 −0.4 keV ) are significantly higher than those inside (1.1 ± 0.1 keV and 1.9 ± 0.1 keV ) at 90% confidence level, which confirm the existence of two temperature jumps at the N-edge and S-edge, respectively. Note that the temperature jumps cannot be smeared out by abundance variations allowed by the data; to show this, in Figure 4 we plot the two-dimensional fit-statistic contours of temperature and abundance at 68%, 90%, and 99% confidence levels inside and outside N-edge and S-edge, respectively, all obtained in the above deprojected fittings.
To estimate the gas flow of the two clumps, we attempt to fit each of the exposure-corrected SBPs with two density models, respectively, by applying the best-fit deprojected spectral parameters (Table 1). The first density model (model A) is composed of two β components as where R is the 3D radius, R c is the core radius, and β is the slope. The second density model (model B) is composed of one truncated power-law component and one β component, where R cut is the truncation radius to be determined in the fittings. For each of the SBPs, an acceptable fit is obtained with model B only (Table 2; Fig. 2), and we show the gas density inside and outside of these two edges in Table 3. The density jump is in a factor of 2.0 +0.4 −0.3 across the N-edge, and 1.4 ± 0.1 across the S-edge.
Following the method of Vikhlinin, Markevitch, & Murray (2001), to estimate the Mach number of gas flow we need to investigate the gas pressure in both the stagnation point and the undisturbed free stream. The gas pressure at the stagnation point must be equal to that inside the edge, which can be well determined by the X-ray gas density and temperature of the N-clump and S-clump (Table 1 and Table 3). Because the gas between the two clumps (Region SN2 and NS3; Table 1) is significantly heated by the merger as shown in §3.2, it cannot be thought of as the gas temperature of free stream. Thus, we assume the undisturbed gas in the north semi-annulus of Nclump (Region NN2) and the south-west semi-annulus of Sclump (Region SS3) as the free stream. Then, we calculate the average thermal gas pressure inside of the edge and in the corresponding free stream as P in and P 0 , and find that the pressure ratio is P in /P 0 = 1.1 +0.5 −0.3 for N-edge and 1.0 ± 0.3 for Sedge (Table 3), respectively, which indicates that the pressure equilibrium has been established across the two edges. Also, from Bernoulli's equation (Landau & Lifshitz 1959) we estimate that the Mach number of the gas flow is M N−edge < 0.8 (corresponding to a velocity of 580 km s −1 ) for the N-clump. Because the above is a rough estimate and no shock-like edge is found in the X-ray image, it is believed that the N-clump moves toward the south in a subsonic flow, which is consistent with that found by Dupke & Martins (2013). For the Sedge, the Mach number is M S−edge < 0.6, corresponding to a velocity less than 430 km s −1 . Based on the above results, we conclude that the N-clump comes from north to merge with the S-clump, and a cold front is observed at its south boundary. At the same time, the S-clump is moving north-east at a slower speed, and correspondingly, the other cold front is formed at the north-east boundary of S-clump. Therefore, the head-on merger is in a stage of the pre-core passage.
In the 1.4 GHz map, the radio source in the center of galaxy NGC 6338 is resolved, and the radio emission displays an X-shaped appearance. The radio lobes, extending to the north-east and south-west directions, are associated with two possible X-ray cavities (Fig. 6), which Pandge et al. (2012) found by analyzing Chandra X-ray data. These indicate that these two radio lobes were inflated by jets originating from the central AGN activity. The radio substructures, extending to the north-west and south-east with the size scale of 8.6h −1 73 kpc (15 ′′ ) and 7.7h −1 73 kpc (13 ′′ ) over 10σ, respectively, are roughly perpendicular to the older radio lobes, and they are coincident with two X-ray filaments ( Fig.  6; Pandge et al. 2012) and HST Hα filaments (Martel et al. 2004). Pandge et al. (2012) also detected HST I-band filaments (usually associated with the interstellar dust) in the center of galaxy NGC 6338, which extends up to about 3.6 kpc in the south-east direction. The spatial correspondence of radio, X-ray, Hα and optical filaments provides a strong evidence that these features has been inflated by jets from the central AGN in its latest outburst. In the VLA 4.9 GHz map, the radio source is not resolved (Fig. 5b).
To the south-east of the NGC 6338 group, we find a radio galaxy with two lobes in both of 1.4 and 4.9 GHz maps, which possibly correspond to a background AGN. In the central region of the two lobes, we find an X-ray pointlike source that is likely associated with the galaxy SSTSL2 J171538.78+572325.8 within 3 ′′ , as shown in Figure 6.

VELOCITY DISTRIBUTION
To investigate the merging status of the NGC 6338 group, we select galaxies from the NASA/IPAC Extragalactic Database (NED) within a radius of 31 ′ (∼1 Mpc) centered at the weighted centroid of the group galaxy distribution (RA=17h15m24s Dec=+57d24m39.6s; Pearson et al. 2015). To including possible substructures a velocity cut of ±2, 000 km s −1 centered on the group redshift (z=0.02824) is applied. Then, 82 galaxies are identified to belong to the group, in which the two nuclei of 2MASX J1715 are defined as two galaxies.
First, we plot the line-of-sight velocity distribution of the member galaxies in Figure 7(a), which shows that a highvelocity plateau is located at about 9, 800 km s −1 . We fit the observed distribution with a single Gaussian profile, and then we calculate the Kolmogorov−Smirnov statistic for the observed distribution against the best-fit Gaussian model (χ 2 /d.o.f. = 63.8/15), which shows that the observed distribution has a probability of < 20% of being Gaussian. We attempt to fit the observed distribution with a two-component Gaussian model. The best-fit (χ 2 /d.o.f. = 23.7/12) gives an average velocity of < v 1 >= 8, 600 ± 40 km s −1 and a corresponding variance of σ v,1 = 430 +40 −30 km s −1 for the main Gaussian component, and < v 2 >= 9, 690 +60 −50 km s −1 and σ v,2 = 160 +50 −40 km s −1 for the high-velocity plateau. By applying the F-test and the Kaye's Mixture Model (KMM; McLachlan & Basford 1988;Ashman, Bird, & Zepf 1994) test, the latter of which is based on a maximum likelihood algorithm, we find that the second Gaussian component is required at the 99% confidence level and preferred at a significant probability of 90%, respectively.
Following the method of Wang et al. (2010), to investigate whether the galaxies in the high-velocity plateau form a real substructure, we divide the identified galaxies into two subgroups: one sub-group with a low-velocity of 7, 500 − 9, 500 km s −1 ) and the other with a high-velocity of 9, 500 − 10, 600 km s −1 ), which consist of 70 and 12 galaxies, respectively. According to the best-fit two-Gaussian model, these subgroups roughly corresponds to two Gaussian components, respectively, with up to about two of the galaxies in the highvelocity sub-group coming from the main Gaussian component. As shown in Figure 7(b), we find that the galaxies belonging to the high-velocity sub-group are distributed mostly in the north-east part, which includes the member galaxies 2MASX J1715 and NGC 6345 (S/S0, M B = 14.8; z = 0.03449). The galaxies in the low-velocity sub-group that is dominated by galaxy NGC 6338, on the other hand, are scattered symmetrically in the field. These results suggest that the galaxy velocity separation has a dynamical nature and the group is undergoing a merger.

DISCUSSION AND SUMMARY
Based on our X-ray analysis, we find that in the central 100h −1 73 kpc of NGC 6338 group an X-ray brightness discontinuity is detected at the south boundary of the N-clump (associated with the high-velocity sub-group), and at the northeast boundary of the S-clump (related to the low-velocity subgroup) the other X-ray edge is also found, each of which is defined as a cold front. Therefore, the group is undergoing a head-on collision that is in the pre-core passage stage.
As shown in Figure 1b and Table 1, both of the subgroups have a cool core that is not significantly affected by the merger. Because both N-clump and S-clump are gas rich, we can use their X-ray properties to simply estimate the mass ratio of two sub-groups. We get the spectrum of N-clump extracting from both Regions NN1 and SN1, and that of Sclump from all the Region NS1, NS2, SS1, and SS2. Then we fit each spectrum with the absorbed APEC model as used in §3.2. The obtained gas temperatures are T N = 1.16 ± 0.07 keV and T S = 1.66 ± 0.04 keV for N-clump and S-clump, respectively. According to the study of Hudson et al. (2010), cool-core clusters have a systematic central temperature drop, as T c ∝ 0.4T vir , where T c is the cool-core temperature and T vir is the virial temperature of the galaxy cluster. Basing on the scale relation of M vir ∝ T 1.65 vir for galaxy groups and clusters (Sun et al. 2009), the merger mass ratio of two sub-groups is R = M N M S ∝ ( T vir,N T vir,S ) 1.65 ∝ ( T N T S ) 1.65 = 1 : 1.8, which supports the merger is most likely to be a major merger. Here, we do not use the velocity variance ratio of two sub-groups ( §4) to calculate the merger mass ratio, because the number of member galaxies of the high-velocity sub-group is small (only 12 galaxies) and the uncertainty of error will be large.
In §3.3, the speed of N-clump is < 1, 010 km s −1 relative to S-clump roughly in the plane of sky. And in §4, the high-velocity subgroup has a velocity of ∼ 1, 090 km s −1 relative to the low-velocity subgroup along the line-of-sight direction. According to the Pythagorean Theorem, the highvelocity sub-group (N-clump) has a comprehensive velocity of < 1, 490 km s −1 to the low-velocity sub-group (S-clump). Assuming the two clumps move along the projected distance 48h −1 73 kpc at their currents velocities, they would totally collide with > 30 million year.
Considering the relation between radio relic luminosity and system total mass (de Gasperin et al. 2014), and the total mass of NGC 6338 group as M 500 = 9.0 ± 0.5 × 10 13 M ⊙ (Pearson et al. 2015), the expected luminosity of one radio relic would be 2.0 × 10 22 Watt Hz −1 , corresponding to the flux density of about 10 mJy at 1.4 GHz at the redshift of NGC 6338 group. One radio relic with a flux of 1.0 mJy and a size scale of 10 × 50 kpc 2 (17.4 ′′ × 87.0 ′′ ) would be detected at the present flux sensitivity of 0.01 mJy/beam (θ 1.4 = 3.3 ′′ × 5.6 ′′ ; §3.4). However, no extended radio emission directly associated with the merger of NGC 6338 group is found ( §3.4). It is possible that the group has a lower merger-caused radio luminosity than that the luminosity-mass relation predicts. In addition, radio relics and halos are usually expected to form after core passage, while the merger in NGC 6338 group in still in the pre-core passage stage. This could be another reason why no merger-caused radio emission is detected in the group.
In the center of galaxy NGC 6338, we find an X-shaped radio structure in the 1.4 GHz map, which is spatially overlapped by two pairs of radio lobes possibly caused by two different AGN activities. The two radio lobes in the northeast and south-west directions, associated with two possible X-ray cavities (Fig. 6), are inflated by jets in an AGN activity; and the others in the north-west and south-east directions originate from the center AGN in its latest outburst, because they spatially correspond to X-ray jets, Hα and optical filaments. Employing a simple assumption that a radio bubble is launched from the nucleus and travels at approximately the sound speed c s , and the time it takes to rise to its projected position is the sound crossing time t c = R/c s , where the sound speed is c s = γkT/(µm H ) ≈ 1100 √ T/5keV km s −1 with γ ≈ 5/3, and µ ≈ 0.62. The estimated inflated time is 1.5 × 10 7 year for the younger lobes. This indicates that the AGN in the center of galaxy NGC 6338 changed the direction of its jets about 1.5 × 10 7 year ago, which is usually explained by axis precession (e.g., Sternberg & Soker 2008;Falceta-Gonçalves et al. 2010).
We thank the Chandra team for making data available via the High Energy Astrophysics Science Archive Research Center (HEASARC). This work was supported by the Ministry of Science and Technology of China (grant No. 2018YFA0404601), the National Science Foundation of China (grant Nos. 11103057, 11433002, 11533004, 11621303 and 61371147). a An absorbed APEC model is used to fit the spectra extracted from the semi-annuli centered on the X-ray peaks of N-clump (Region NN1 − 2 and SN1 − 2) and S-clump (Region NS1 − 3 and SN1 − 3), and Box (a−l) as shown in Fig. 3. The redshift and absorption are fixed to z = 0.02824 and the Galactic value N H = 2.23 × 10 20 cm −2 (LAB Survey of Galactic HI; Kalberla et al. 2005), respectively. b The PROJCT model in XSPEC v12.4.0 is used to deproject the spectra in the south semi-annuli of N-clump (Region SN1 − 2) and the north-east semi-annuli of S-clump (Region SN1 − 3), respectively. Table 2 Acceptable Fits to the Surface Brightness Profiles across the N-edge and S-edge a  (Fig. 2), which are extracted from the south semi-annuli of N-clump and the north-east semi-annuli of S-clump (Fig. 1), respectively. Best-fit deprojected spectral parameters (Table 1) are adopted in the fittings to calculate gas emission. For each of SBPs, the acceptable fit is obtained with model B only. We show them here.  Fig. 3) to be assumed as that of the free stream for the N-edge. b Gas temperature in Region SS3 (Table 1 and Fig. 3) to be assumed as that of the free stream for the S-edge. , respectively, extracted from the south semi-annuli of the N-clump and the north-east semi-annuli of the S-clump as shown in Fig. 1. Dotted (model A: two β components) and solid (model B: one truncated power-law + β components) lines show the best-fits obtained with the two density models described in §3.3, respectively. (middle) Chandra ACIS-I temperature profiles for N-clump (c) and S-clump (d), extracted from the same region as SBPs. (down) Chandra ACIS-I metal abundance profiles for N-clump (e) and S-clump ( f ), extracted from the same region as SBPs. The dotted data in (c − f ) present the deprojected spectral results. All the values of gas temperature and metal abundance are listed in Table 1.  Table 1. Fig. 4.-Fit-statistic contours at 68% (solid), 90% (dashed), and 99% (dotted) confidence levels for the gas temperature and metal abundance derived with the deprojected APEC model in Region SN1 − 2 (a) across the N-edge (Fig. 2c and e) and Region NS2 − 3 (b) across the S-edge ( Fig. 2d and f ), respectively.   -(a) Line-of-sight velocity distribution of 82 member galaxies identified in the NGC 6338 group. The distribution is fitted with a two-Gaussian model (solid) and a single Gaussian model (dashed; §4), respectively. (b) DSS optical image for central 2, 100 × 2, 100 kpc 2 (62 ′′ × 62 ′′ ) region of the group, where the low-velocity (v < 9, 500 km s −1 ) and high-velocity (v > 9, 500 km s −1 ) member galaxies are marked with small and big circles, respectively. The positions of 2MASX J1715's two nuclei are very close on the image, which is pointed out with one big circle for clarity.