Abstract
A detailed optical and infrared photometric analysis of the open star cluster IC 361 is given in the present paper. On studying the radial density profile, radial extent of the cluster is found to be \(8.0\pm 0.5\) arcmin. The basic physical parameters of the cluster such as \(E(B-V) = 0.56\pm 0.10\) mag, \(E(V-K)=1.72\pm0.12\) mag, \(\hbox {log(Age)}=9.10\pm 0.05\), and \((m-M)_{0} = 12.54\pm 0.05\) mag are obtained using the colour–colour and colour–magnitude diagrams. IC 361 is found to be located at a distance of \(3.22\pm 0.07\) kpc. Using the archival proper motion catalogues, we estimate the mean proper motions of IC 361 as \(4.97\pm 0.17\) mas yr\(^{-1}\) and \({-}\,5.80\pm 0.18\) mas yr\(^{-1}\) in the direction of RA and Dec, respectively. A uniform distribution of mass between small scale and large scale is confirmed by MF slope of IC 361. However, the mass function slope of cluster region is found to be \(-1.06\pm 0.09\), which is too low compared to the Salpeter value. Our study is further showing a dynamical relaxation behaviour of the cluster IC 361.
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1 Introduction
The physical quantities of an individual star cluster are required to understand the processes of star formation and stellar evolution in the galaxy. For this purpose, author selected an open cluster (OC) IC 361 of Camelopardalis constellation [1]. Since observed regions of clusters are contaminated by the field stars, therefore, a comprehensive membership analysis is needed to confirm the stellar membership of clusters and to decide their periphery. In the case of IC 361, it is well detached from the field stars and poorly studied due to its faintness [2]. It lies in the second galactic quadrant. A considerable interstellar reddening is demonstrated by IC 361 due to the presence of immediate vicinity of the Camelopardalis dark clouds [3]. It is approximately 2.5 kpc away from Earth, and it shows the high value of reddening, \(E_{B-V} = 0.55\), with the age range from 0.5 to 1 Gyr [1]. A deep and multi-colour photometry of IC 361 is needed to precise determination of fundamental parameters and its dynamical behaviour. On this background, the comprehensive analysis of UBVRI and JHK photometric data is carried out in the present study.
This paper is organized as follows: The photometric observation of the cluster is described in Sect. 2. The centre coordinates and size of cluster IC 361 are computed in Sect. 3. The results of parameters through colour–magnitude diagrams (CMDs) and two colour diagrams (TCDs) analysis are given in Sect. 4. Section 5 is devoted to identify the probable members of IC 361 and its mean proper motions. Dynamical study of the cluster has been carried out in Sect. 6. The final conclusions and discussion are stated in Sect. 7.
2 Photometric observation and comparison with previous study
Johnson-Cousins UBVRI photometry of stars in the field of IC 361 was obtained on 24 December 2013, using the 1.04-m Sampurnanand telescope at Nainital, India. The observation details of this cluster are given in Table 1. On the same night, we also observed Landolt’s standard field: SA92 [4]. A total of 24 standard stars are identified in the field of view (FOV) of SA92 and their air-mass ranges from 1.01 to 3.41. The usual image processing procedures (bias subtraction, flat fielding, and cosmic ray removal) were performed through IRAFFootnote 1 software package. Photometry of the frames was performed using the DAOPHOT II profile fitting software [5]. The resultant transformation coefficients for the standard stars are also listed in Table 1, and photometric error with magnitude is depicted in Fig. 1a. The rms scatter values of the transformation of standard photometry are found to be 0.037, 0.022, 0.005, 0.007 and 0.013 for U, B, V, R and I bands, respectively. The observed field of view (FOV) of the cluster is \(\sim 13 {\times } 13\,\mathrm{arcmin}^2\), and we found 1883 stars in the FOV of the cluster.
In order to transform CCD pixel coordinates to celestial coordinates, we used the online digitized ESO catalogue (included in the skycut software) as an absolute astrometric reference frame. A linear astrometric solution was derived for the V filter reference frame by matching positions of 170 well-isolated bright stars. The ccmap and cctran routines are utilized for this purpose. We found 276 common stars between present photometry and Vilnius photometry [3], and V-magnitude difference between these datasets is shown in Fig. 1b. The mean difference of both datasets is \(-0.001\) mag, and its error is found to be 0.002 mag.
3 Centre and radius of the cluster
The centre coordinates (\({\alpha },{\delta }\)) of cluster IC 361 are found to be \((4^h 18^m 56^s\pm 0.2^s\), \(+58^\circ \,15'\,18''\,\pm 3'')\). Similarly, the equivalent pixel coordinates of centre of observed reference of IC 361 frame are given as \(({x,y})=(465\pm 4\), \(545\pm 4\)). The radial density profile (RDP) of open cluster is used to determine the cluster radius. The RDP is constructed by determining the stellar density in concentric rings of equal width around the cluster centre. We choose a thickness of about 1 arcmin (\(\sim \) 80 pixels) for each ring in order to have statistically significant number of stars in each radial zone. The stellar density (\(\rho _{r}\) ) at the distance r from the cluster centre is defined by the following empirical formula [6]:
where \(\rho _{0}\) is the field subtracted peak stellar density (max. model density) and \(\rho _{f}\) is the background density. The \(r_{c}\) is core radius of the cluster defined as a distance from the centre at which the density \(\rho _{r}\) becomes half of the \(\rho _{0}\). The cluster radius is determined where RDP intercepts the background density. The prescribed background density is estimated as the average of first three approximate values of field densities and estimated background stellar densities of utilized datasets of each catalogue, and is depicted by green line in each panel of Fig. 2, whereas the model stellar densities are depicted by the red lines. The present analysis indicates that the different seller numbers of different catalogues provide the different values of radius and are listed in Table 2. Resultant values are computed by taking the straight mean of the table values. Thus, the radius and core radius of IC 361 are found to be \(8.24\pm 0.32\) arcmin (\(\sim \) \(645\pm 25\) pixels) and \(2.34\pm 0.47\) arcmin, respectively.
4 Analysis through the CMD and TCD
4.1 Nature of extinction law
As the light is emitted from the star cluster, the light or it passes through the interstellar dust and gas, scattering and absorption of light take place. Since the absorption and scattering of the blue light are more compared to the red light, the stars appear reddened. The law of selective absorption is the same for all directions of the galaxy. The ratio of total extinction (\(A_{V}\)) to reddening [\(E(B-V)\)] is known to be total-to-selective-extinction ratio (\(R_{V}\)). The normal value of \(R_{V}\) comes to be 3.1 for galaxy, and it is known to be normal reddening law. Generally, normal reddening law is applicable when dust and intermediate stellar gases are absent in the line of sight of the cluster [7]. However, the reddening law is expected to be different in the presence of dust grains. We have investigated the nature of reddening law using \((V-\lambda )/(B-V)\) TCDs [8], where \(\lambda \) is any broad band filter, namely R, I, J, H, K, \(W_1\), and \(W_2\). Here, \(W_1\) and \(W_2\) are mid-IR passbands used for wide-field IR Survey Explorer (WISE [9]). The \((V-\lambda )/(B-V)\) TCDs have been widely used to separate the influence of the extinction produced by the diffuse interstellar material from that of the intra-cluster medium [8]. Therefore, we constructed the resultant \((V-\lambda )/(B-V)\) diagram in different wavelength bands, as shown in Fig. 3a. A best linear fit in the TCD of cluster gives the value of slope (\(m_\mathrm{cluster}\)) for the corresponding TCD. The resultant values of the \(m_\mathrm{cluster}\) for seven colours are listed in Table 3 along with their normal values. Our slopes are quite comparable with those obtained for the diffuse interstellar material.
A total-to-selective extinction \(R_\mathrm{cluster}\) is determined using the following relation [10]
Assuming the value of \(R_\mathrm{normal}\) for the diffuse interstellar material as 3.1, we determined \(R_\mathrm{cluster}\) in the first five colours listed in Table 3. These values indicate that the value \(R_\mathrm{cluster}\) is found to be high for the shorter effective wavelength with reference of V optical band, whereas the values of \(R_\mathrm{cluster}\) are low for bands, having the high effective wavelength compared to the V optical band. The mean value of \(R_\mathrm{cluster}\) is estimated as \(R=2.94\pm 0.11\) for the cluster IC 361 through the last four computed values of \(R_\mathrm{cluster}\); moreover, this mean value of \(R_\mathrm{cluster}\) is low than of normal reddening law.
After using the estimated value of \(R_{cluster}\), author computed the distance of cluster as \(3.37\pm 0.15\) kpc. This value is \(4.45 \%\) greater than the estimated distance by standard value of \(R_\mathrm{normal}\) (given in Section 4.4).
4.2 (\(U-B\)) vs (\(B-V\)) TCD
The reddening, \(E(B-V)\), in the cluster region, is estimated using the \((U-B)\) vs \((B-V)\) TCD. In Fig. 3b, we plot TCD for the members found in our study. We also draw zero age-main sequence (ZAMS [11]) for observed MS stars on (\(U-B\)) vs (\(B-V\)) diagram. Here, we assume a solar metallicity for the cluster and a reddening vector of \(E(U-B)/E(B-V)=0.72\) [12]. The error of estimated reddening is calculated by using the relation [13]
The derived reddening \(E(B-V)\) from our study is \(0.56\pm 0.10\). The colour excesses \(E(V-R)\) and \(E(V-I)\) are estimated by the relations \(E(V-R)=0.60 \times E(B-V)\) [14] and \(E(V-I)=1.25 \times E(B-V)\) [15], respectively. In this connection, the values of colour excesses of \(E(V-R)\) and \(E(V-I)\) are computed to be \(0.33\pm 0.06\) and \(0.7\pm 0.12\) mag, respectively.
4.3 Reddening in near-infrared bands
The two-colour diagrams (TCDs) plots of various sets of two colours (magnitude difference of two bands) are important tools for investigating the nature of extinction law, dependency with each other and their variation from normal values [16]. We are prescribing about two TCDs as below,
4.3.1 (V-K) vs (J-K) TCD
A \((V-K)\) vs \((J-K)\) diagram is used to determine the interstellar extinction in the near-IR (NIR) range. In Fig. 4a, we plot \((V-K)\) vs \((J-K)\) diagram, where we also overplot Marigo isochrones of solar metallicity by shifting the line in the direction of reddening vector \(\frac{E(J-K)}{E(V-K)}=0.173\). In this way, we obtained colour excesses of \(E(V-K)=1.72\pm 0.05\) mag and \(E(J-K)=0.29\pm 0.03\) mag. The relation \(R=1.1 \times \frac{E(V-K)}{E(B-V)}\) [17] was used to estimate the corresponding value of reddening. In Fig. 4a, we draw reddening vectors \(\frac{E(V-K)}{E(B-V)}\) by shifting for the reddening values in the NIR bands (continuous line) and optical bands (long-dashed line). We yield \(E(B-V)=0.62\pm 0.03\) mag in the direction of the cluster, which is slightly higher than that was determined in the optical band. One possibility for the discrepancy is the presence of a small IR excess for stars in the cluster IC 361. However, excess emission in the cluster IC 361 is not consistent with many relatively young clusters. Thus, IC 361 is an old age cluster with low IR-excess.
4.3.2 \((B-V)\) vs \((J-K)\) TCD
\((B-V)\) vs \((J-K)\) TCD of IC 361 is shown in Fig. 4b. The Marigo isochrone is used to know the relationship between \(E(B-V)\) and \(E(J-K)\). The colour excesses \(E(B-V)\) and \(E(J-K)\) of IC 361 are found to be 0.56 and 0.30 mag, respectively. As a result, the \(E(J-K)\)/\(E(B-V)\) ratio for IC 361 is computed to be 0.54, which is close to the literature value, i.e. 0.56 [16]. This variation is possible due to the different value of total-to-selective-extinction from normal value. The red line of Fig. 4b represents Marigos isochrone without any shift, whereas the blue line shows the best-fitted line after shift of 0.56 mag in x-direction and 0.30 mag in y-direction, respectively.
4.4 Age and distance from CMDs
For the determination of age and distance of the cluster, we draw the \((B-V)/V\) and \((V-I)/V\) CMDs for probable members of cluster as illustrated in Fig. 3c. To find the probable members of IC 361, we use a radial cut to get rid of distant field stars. The value of radial cut is equivalent to the radius of cluster radius from the centre, and green dots of Fig. 3c represent those stars which are laying inside the cluster periphery of radial cut. For more precise calculation, author also used a statistical cleaning approach to get confirm probable members of cluster, and these confirm probable members of IC 361 which are depicted by the red dots in Fig. 3c. In this connection, the constructed CMDs show a well populated but broad main sequence (MS) star that may be due to photometric errors and/or presence of binary stars within the cluster. The variable reddening across the cluster region could also be the cause of the broad MS. We overplot Marigo’s theoretical isochrones [18] on the CMDs by varying the distance modulus and age simultaneously in both \((B-V)/V\) and \((V-I)/V\) CMDs while keeping reddening \(E(B-V)=0.60\) mag and \(E(V-I)=0.75\) mag fixed as determined in the previous subsection and assuming \(E(V-I)=1.25 \times E(B-V)\). From the best visual isochrone fit to the varying age and distance combinations on the MS stars, we obtained a distance modulus \((V-M_V)=14.4\pm 0.0.10\) mag and \(log(Age)=9.10\pm 0.05\) (yr) for the cluster IC 361. Employing the correction for the reddening and assuming a normal reddening law (see Sect. 4.3), this corresponds to a true distance modulus \((m-M)_0 = 12.54\pm 0.05\) mag or a distance of 3.22±0.07 kpc for the cluster. Our estimated distance is close to the literature one, i.e. 3.3 kpc [2].
Though isochrone fitting is often used to estimate the age of the cluster in the absence of valuable spectroscopic observations, it should be kept in mind that determining precise age through isochrone fitting in clusters, where no evolved stars are found, is very difficult as it contains a large uncertainty on this value.
5 Mean proper motion and probable members
The mean proper motion value of the cluster is the mean value of proper motion values of its probable members. Probable members of IC 361 are found through the field star decontamination. For this purpose, we have applied the CMRD [16] approach to find clear stellar sequence of studied cluster. The x-axis and y-axis of CMRD are the colour/magnitude ratio (CMR) and stellar V-magnitude, respectively. In the present case of IC 361, the values of stellar CMR have normalized stellar colour \((B-V)\) values with the V-magnitude. The CMR value is found to be 0.08 for brighter stars of cluster, and this value is used to separate cluster’s stellar sequence from the field sequence as depicted in Fig. 5a. The cluster radius is found to be 8 arcmin in the present analysis or a diameter of \(16\pm 1\) arcmin. Since the estimated diameter is greater than the size of observed optical frame as well as other available optical catalogues, therefore, we cannot utilize these catalogues for statistical colour–magnitude cleaning [19] due to observations of limited region of cluster. The available 2MASS data of field region of IC 361, however, does have a sufficiently wide field of view to satisfy our need. As a result, NIR JHK data of cluster is used to further decontamination of field stars. Since the required area of selected field region is equivalent to the enclosed area of cluster periphery, therefore, the disc size of field region for IC 361 is taken to be \(10.0\,\mathrm{arcmin}~{\le }~r~{\le }~12.8\,\mathrm{arcmin}\).
After iterating the cleaning procedure for each field region star, we found 850 probable members on the statistically cleaned CMDs [19]. The proper motion values of these probable members are extracted from the PPMXL catalogue [20], and the proper motion distribution of probable members is depicted in Fig. 5b. The x-axis and y-axis components of stellar proper motion are indicated by \(\mu _{x}\) and \(\mu _{y}\), respectively, and these values are expressed as \(\mu _{x}=\mu _{\alpha } ~cos{\delta }\) and \(\mu _{y}=\mu _{\delta }\). In the equatorial coordinate system, the prescribed \(\mu _{\alpha }\) and \(\mu _{\delta }\) are the components of proper motion in the direction of RA and Dec, respectively. Thus, \(\mu _{x}\) is a shrink value of \(\mu _{\alpha }\) by a factor of \(cos{\delta }\) due to the changing angular size of circles of constant RA when moving from the celestial equator towards the celestial pole. Such shrinking effect of \(\mu _{\alpha }\) is known as the cos(Dec) effect in the proper motion.
The location of these probable members around best-fitted isochrones of \((B-V)/V\) and \((J-K)/J\) CMDs confirms the main sequence of IC 361 in Fig. 5c, d. The resultant probable members are further utilized to estimate the mean proper motion of IC 361 through 3\({\sigma }\) clipping approach. In this approach, the stars which do not fall within 3\(\sigma \) value of the mean are rejected for estimation. After 3\({\sigma }\) clipping, we found 725 probable members to estimate the mean proper motion as depicted by blue dots in Fig. 5b. In this connection, the mean proper motion values of IC 361 are found to be \(\bar{\mu _{x}} = 4.97 {\pm }0.17\) mas yr\(^{-1}\) and \(\bar{\mu _{y}} = -5.80\pm 0.18~{\text{mas~yr}}^{-1}\) in RA and DEC directions, respectively.
6 Dynamical study of the cluster
6.1 Luminosity and mass functions
The luminosity function (LF) is the total number of cluster members in different magnitude bins. The estimated number of stars in each magnitude bin for the cluster \((N_\mathrm{C})\) is given in Table 4. One can see that number of stars reduced significantly after the 19 mag, which is due to incompleteness factor. Artificial star tests [21] are used to determine incompleteness and to modify the photometric errors of science images. Such studies indicate that generally, the data incompleteness increases with the stellar faintness [22]. In the present catalogue, it is better than 90% up to 19 mag. In Fig. 5c, the green dots represent the identified stars in the FOV of IC 361 and the red dots represent the probable members of cluster. It is noted that the probable members are not appeared after 18 V-mag. The turn point of best-fitted isochrone on main sequence of IC 361 is found at near of 15 V-mag. Therefore, we have not applied any correction to the luminosity and mass functions between V-mag range 15-18 derived in the present study.
The initial mass function (IMF) is defined as the distribution of stellar masses per unit volume in a star formation event, and knowledge of IMF is very effective to determine the subsequent evolution of cluster. The direct measurement of IMF is not possible due to the dynamical evolution of stellar systems though we can estimate the present mass function (MF) of cluster. The MF is defined as the relative numbers of stars per unit mass and can be expressed by a power law \(N(\log M) \propto M^{\Gamma }\). The slope, \(\Gamma \), of the MF can be determined from
where \(N\log (m)\) is the number of stars per unit logarithmic mass. In the case of known values of age, reddening, distance and metallicity, the masses of probable members of any cluster can be determined by comparing their observed magnitudes with those predicted by a stellar evolutionary model. The MF determined for the cluster is given in Table 4. The effect of field star contamination is negligible for estimation of MF due to fact that most probable members (MPMs) are used for this purpose in the present study. Figure 6 shows the MF in the cluster fitted for the MS stars with masses \(1.104{\le }M/M_{\odot }~<~2.345\). The error bars have computed assuming Poisson statistics. The MF slope (\(\Gamma \)) for cluster comes out to be \(-1.06{\pm }0.09\), which is low compared to Salpeter MF slope of \({-}\) 2.35 [23]. The obtained value of slope is close to the unity. An unit MF slope of a cluster corresponds to a uniform distribution of mass between small and large scales.
6.2 Mass segregation
The stellar encounters of the cluster’s members cause mass segregation. In the processes of mass segregation, the higher-mass cluster members gradually sink towards the cluster centre by transferring their kinetic energy to the more numerous lower-mass stellar members of the cluster [24]. With the dynamical evolution of the cluster, the spatial mass distribution in the cluster changes with time. To investigate the dynamical evolution and mass segregation process in the cluster IC 361, the cumulative radial stellar distribution of the probable members for various mass ranges is shown in Fig. 7 and also given in Table 5. It is seen that MS slope does not become steeper as the radial distance from the cluster increases. This clearly suggests that the mass segregation is not taking place in the cluster. To further study the mass segregation in more detail, we plot the variation of mean mass along the radial distance for the probable members in Fig. 8. The average mass of centre bin is high, as expected.
Our study indicates that the higher and lower mass stars are uniformly distributed in the cluster region. To understand whether it is an imprint of star formation process in the clusters and/or result of dynamical evolution, we determined dynamical relaxation time, \(T_R\), which is the time in which individual stars in the cluster exchange energies and their velocity distribution approaches Maxwellian equilibrium. It can be expressed as
where \(T_R\) is in Myr, N is the total number of cluster members, \(R_h\) is the radius (in parsecs) containing half of the cluster mass and \({\bar{m}}\) is mean mass of the cluster members in solar units [25]. We estimated a total of 1362 member stars in the mass range \(0.93 \le M/M_\odot < 2.4\). The total mass of the cluster is found to be \(\sim 2198.95 M_\odot \) for IC 361, which gives an average mass of \(\sim 1.61 M_\odot \) per star. The contribution of the low-mass stellar population is critical for constraining the total cluster mass, which is crucial in understanding the dynamical evolution and the long-term survival of a cluster [26]. It can be seen that the half-radius of the cluster, \(R_h\), plays an important role in the determination of the dynamical relaxation time, \(T_R\). To determine the \(R_{h}\), author has estimated the radial distance of each member from the centre of cluster with mass. In this connection, members are arranged in the ascending order with respect to the radial distance and calculated the cumulative mass for the radial distance of each member. The cumulative mass of farthest member of cluster is equal to the total mass of cluster. The radial distance of a star, having cumulative mass equal to the half of total mass of cluster, is taken as the half mass radius of studied cluster. We obtained a half-mass radius for the cluster as 1.00 pc, which is \(\sim 54.8\%\) of the cluster radius. A half-mass radius larger than half of the cluster radius suggests that the inner region still has a deficiency of massive stars in the core region of the cluster. We estimated the dynamical relaxation time \(T_R = 9.46\) Myr for the cluster. \(T_R\) determined in the present study is much less than the present age of about 1.3 Gyr, which suggests that cluster IC 361 is dynamically relaxed.
7 Results and discussion
Open clusters are important tools for understanding of the evolution phenomenon in galaxies because they provide information on star formation history. In the present study, we have constructed a complete \(UBVRIJHKW_1W_2\) catalogue for the cluster IC 361 by supplementing our photometric data with the 2MASS NIR and WISE mid-IR surveys. Using a V -band data of the present catalogue for the stars brighter than \(V = 18\) mag, we found that the core and cluster radius are \(2.0\pm 0.4\) arcmin and \(8.0\pm 0.5\) arcmin, respectively. Using probable members, we derived the reddening in optical band using \((U - B)/(B - V )\) diagram and in NIR band using \((V - K)/(J - K)\) diagram. The values of reddening were obtained as \(E(B-V) = 0.56{\pm }0.10\) mag and \(0.62{\pm }0.03\) mag in optical and NIR, respectively. Since IC 361 shows a differential extinction across the cluster region as well as IR colour excess, it indicates that the stars are still embedded in the parent molecular gas and dust.
Based on the \((B -V )/V\) and \((V -I)/V\) CMDs and a visual fitting of isochrones for solar metallicity given by Marigo et al. (2008) to the blue sequence on the CMD, we determined a distance of \(3.22{\pm }0.07\) kpc and log(age) of \(9.10\pm 0.05\) for the cluster IC 361. At this distance, we estimated a respective core and cluster radii of \(1.87\pm 0.18\) pc and \(7.50\pm 0.94\) pc for this cluster. We estimated the average total-to-selective extinction value as \(2.94{\pm }0.11\) that is low compared to the normal value but in a reasonable agreement. The mean proper motion of the cluster was determined using the PPMXL catalogue and found to be \(4.97 \pm 0.17\) mas/yr and \(-5.80 \pm 0.18\) mas/yr in the direction of RA and DEC, respectively. The MF slope of probable stars of the cluster is found to be \(1.06\pm 0.09\) in the mass range \(1.10{\le }M/M_{\odot } < 2.34\).
8 Conclusion
The physical parameters of IC 361 are derived under this study. The membership analysis of IC 361 indicates least percentage of probable and statistical cleaned members at fainter limits of extracted stellar sequence within the field of view (FOV) of cluster. In the case of IC 361, we have not found any evidence of a stepper MF slope with the radial distance, which suggests that the mass segregation does not take place in the cluster. The relaxation time of the cluster has found to be much lower than its age, which implies that the cluster has long ago dynamically relaxed.
Notes
Image Reduction and Analysis Facility (IRAF) is distributed by the National Optical Astronomy Observatories, which are operated by the Association of Universities for Research in Astronomy, Inc., under cooperative agreement with the National Science Foundation.
References
J Piccirillo and W L Stein Astron. J. 83 971 (1978)
J Zdanavicius, R P Boyle, F J Vrba, K Zdanavicius and R Bartasiute IAU Symp. 266 557 (2009)
J Zdanavicius, R Bartasiute, R P Boyle, F J Vrba and K Zdanavicius Baltic Astron. 19 63 (2010)
A U Landolt AU Astron. J. 104 340 (1992)
P B Stetson Publ. Astron. Soc. Pac. 99 191 (1987)
I King Astron. J. 71 64 (1966)
C Sneden, R D Gehrz, J A Hackwell, D G York and T P Snow Astrophys. J. 223 168 (1978)
R Chini and W F Wargu Astron. Astrophys. 227 213 (1990)
E L Wright, P R M Eisenhardt, A K Mainzer et al. Astron. J. 140 1868 (2010)
Y C Joshi, L A Balona, S Joshi and B Kumar Mon. Not. R. Astron. Soc. (MNRAS) 437 804 (2014)
Schmidt-Kalar Th., In: Landolt/Bornestein, Numerical Data and functional Relationship in Science and Technology. Scaifers K, Voigt HH., (editors) Springer-Verlog, Berlin; New Series, Group VI. 26 14 (1982)
J F Dean, P R Warren and A W J ousins Mon. Not. R. Astron. Soc. 183 569 (1978)
R L Phelps and K A Janes Astrophys. J. Suppl. Ser. 90 31 (1994)
S Lata, A K Pandey, R Sagar and V Mohan Astron. Astrophys. 388 158 (2002)
A R Walker Mon. Not. R. Astron. Soc. 213 889 (1985)
G C Joshi and R K Tyagi Mon. Not. R. Astron. Soc. (MNRAS) 455 785 (2016)
D C B Whittet and I G van Breda Mon. Not. R. Astron. Soc. 192 467 (1980)
P Marigo, L Girdardi, A Bressan, M A T Groenewegen, L Silva and G L Granato Astron. Astrophys. 482 883 (2008)
G C Joshi, Y C Joshi, S Joshi, S Chowdhury and R K Tyagi Publ. Astron. Soc. Aust. (PASA) 32 22 (2015)
S Roeser, M Demleitner and E Schilbach Astron. J. 139 24440 (2010)
R Sagar and T Richtles Astron. Astrophys. 250 324 (1991)
S Sharma, A K Pandey, K Ogura, T Aoki, K Pandey, T S Sandhu and R Sager Astron. J. 135 1934 (2008)
E E Salpeter Astrophys. J. 121 161 (1955)
R D Mathieu and D W Lathem Astron. J. 92 1364 (1986)
L Jr Spitzer and M H Hart Astrophys. J. 164 399 (1971)
R deGrijs and G Parmentier Chin. J. Astron. Astrophys. 7 155 (2007)
Acknowledgements
GCJ is also acknowledged to ARIES, Nainital for providing observing facility duration from October 2012 to April 2015. GCJ is thankful to Honourable Dr. A.K. Pandey, Director, ARIES (Nainital) to permit him to use the gathered raw data of candidate through the letter No. AO/2018/41 on date April 12, 2018. This publication made use of data products from the Two Micron All Sky Survey, which is a joint project of the University of Massachusetts and the Infrared Processing and Analysis Center/California Institute of Technology, funded by the National Aeronautics and Space Administration and the National Science Foundation. This publication also makes use of data products from the Wide-field Infrared Survey Explorer, which is a joint project of the University of California, Los Angeles, and the Jet Propulsion Laboratory/California Institute of Technology, funded by the National Aeronautics and Space Administration.
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Joshi, G.C. A near-infrared and UBVRI photometric analysis of the open cluster IC 361. Indian J Phys 96, 659–669 (2022). https://doi.org/10.1007/s12648-021-02020-5
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DOI: https://doi.org/10.1007/s12648-021-02020-5