2 BACKGROUND AND THEORY

2.2. Theory

The absolute V magnitude (M_V ) of a star is given by the relation:

(1) \begin{equation} M_V = m_V - 5\;\log _{10} (d) + 5 - A_V ;\end{equation}

where m_V denotes the apparent V magnitude, d is the distance of the star in parsec, and A_V is the extinction correction due to interstellar material.

As stated above, m_V can be read directly from field H5 of the Hipparcos catalogue and the distance d (in pc) can be calculated from trigonometric parallax (in arcsec) from the relation (e.g., Zeilik & Gregory Reference Zeilik and Gregory1998):

(2) \begin{eqnarray} d &=& ( {{1 / \pi }} ) = ( {{{10^3 } / {\pi _{\rm H} }}} )\;{\rm in}\,{\rm pc} \Rightarrow\nonumber\\ d &=& ( {{{3.085\,68 \times 10^{21} } / {\pi _{\rm H} }}} )\;{\rm in}\,{\rm cm;}\end{eqnarray}

where π is the parallax in arcsec and π _H is the parallax in milliarcsec as given in Hipparcos catalogue (Table 1: H11).

The extinction A_V can be estimated from the column density of hydrogen by using the relationship (Guver & Ozel Reference Guver and Ozel2009):

(3) \begin{equation} \begin{array}{rl} N_{\rm H} & = ( {2.21 \times 10^{21} } ) \cdot A_V \quad \Rightarrow \\ A_V & = {{N_{\rm H} } / {( {2.21 \times 10^{21} } ) = \ }}{{N \cdot d} / {( {2.21 \times 10^{21} } )}}\\ & = {{3.085\,68} / {( {2.21 \cdot \pi _{\rm H} } )}} = {{1.396\,24} / {\pi _{\rm H} }}, \\ \end{array}\end{equation}

where N _H = N.d is the column density of hydrogen along the direction of the star and N is the average number of hydrogen atom, molecule or ion per cm³ along the direction of the star of distance d expressed in cm. The value of N within 100 pc along various directions of the sky is less than 1 cm⁻³ (Cash, Bowyer, & Lampton Reference Cash, Bowyer and Lampton1979). In the calculation of column density of hydrogen N _H, we put N = 1 cm⁻³ so that a maximum value of A_V can be obtained from Equation (3). Replacing Equations (2) and (3) in Equation (1), we have the following:

(4) \begin{equation} M_V = m_V - 10 + 5\log _{10} ( {\pi _{\rm H} } ) - {{1.396\,24} / {\pi _{\rm H} }}.\end{equation}

Thus, knowing m_V and π_H, the absolute V magnitude M_V of a star can be calculated by using the above relation.

2.3. Error estimation

To estimate the maximum possible error in determining M_V from Equations (1) and (4), which may come across due to the lack of accurate knowledge of m_V and d, we can take the differential of Equations (1) and (4) which leads to

(5) \begin{equation} \begin{array}{rl} \delta M_V & = \left| {\delta m_V } \right| + (5/In(10))\left| {\delta d/d} \right| + \left| {\delta A_V } \right| \\ & = \left| {\delta m_V } \right| + (5/In(10))\left| {\delta \pi _{\rm H} /\pi _{\rm H} } \right| + 1.396\;24\left| {\delta \pi _{\rm H} /\pi _{\rm H} ^2 } \right|. \end{array}\end{equation}

In order to get maximum possible error in M_V we should use only positive values of the errors because otherwise they may cancel each other, reducing the error limit.

4 ANALYSIS

We separate out those stars with M_V – M_V0 greater than the expected maximum error for that star calculated from Equation (5) (shown in Figure 4). It is evident from ESA (Reference Perryman1997) that the experimental error in V magnitude is ~10⁻². To assign a maximum error limit in m_V we put m_V = 1 in Equation (5). The maximum and minimum of the Hipparcos magnitude H _p of variable stars were obtained from H49 and H50 respectively. Variable stars which have a maximum variation in H _p more than 1 mag (|H49–H50| > 1) and the multiple star systems have also been rejected from List-1. To calculate the maximum error in parallax part of Equation (5), we put δπ = 1.5σ_π so that a maximum ± error assigned to δπ be 3σ_π (obtained from H16). Thus in a final list we get a total of 2 853 stars out of the 21 595 stars of List-1 which significantly deviate from the standard photometric behaviour. These stars are plotted in Figure 4 to show the deviation of (M_V – M_V0 ) versus distance dependence.

Figure 4. Same as Figure 3 but shows only those stars with errors more than ±δM_V .

We find that 2 853 number of stars of List-1 show a greater value of (M_V – M_V0 ) than greatest possible error in M_V . This is because of the fact that M_V0 values that have been used here are just average values that have been considered to be standard for a given spectral class. However in reality, the absolute magnitude may vary within a given range from the standard value which introduces an additional deviation which was not included in δM_V . In any case, if the absolute value of the deviation (i.e., |M_V –M_V0 |) is equal to 5 mag or more, it is large enough to say that the error is abnormal, because, it can be easily realised from H–R diagram that addition or subtraction of 5 mag in M_V of a star must change its spectral class, whereas error in M_V0 cannot be so high which is evident from correct match between M_V and M_V0 for about 87% of the stars (Figures 1(a), 2, and 3). Therefore, the stars with abnormal deviation must have been wrongly spectrally classified, or the extinction of the interstellar medium is very different from the calculated A_V in which we have assumed a constant N = 1 cm⁻³ (Cash et al. Reference Cash, Bowyer and Lampton1979).

Those stars from the 2 853 stars which show a difference in absolute magnitude greater or equal to 5 mag (|M_V – M_V0 | ≥ 5) are separated out and compiled in Table 2. We then check their classification in the SIMBAD database. We found that some of these stars have already been corrected for spectral classification and show much lower difference with the new spectral class. The absolute magnitude derived for this new spectral classification is shown as M′_V0 in the 9th column and (|M_V – M′_V0 |) in the 10th column of Table 2. The new spectral classification and the reference number of these changes in spectral type are in the 8th and 11th column respectively. The relevant citations corresponding to these numbers are mentioned below in the Table 2. The remaining stars for which we did not find any record of correction in MK spectral classification are marked as ‘unchanged’ in the 8th column in Table 2.

For the stars that still show a deviation of |M_V – M_V0 |≥ 5 or |M_V – M′_V0 | ≥5, we need to verify if it is a result due to variation in interstellar extinction. We therefore plot the position of these stars in galactic co-ordinates in an Aitoff projection shown in Figure 5. The stars with d < 50 pc have been plotted with triangular points while the stars between 50 pc ≤ d < 100 pc have been plotted with circular points. We notice that these stars are distributed all across the galactic sky. We now over-plotted these positions over integrated opacity derived by Vergely et al. (Reference Vergely, Valette, Lallement and Raimond2010) (Figure 6) for a line of sight distance of 250 pc so that it can be understood if they belong to any dark region of our Galaxy which may introduce an abnormal extinction in magnitude. From Figure 6, we see that the position of the stars does not correlate with the high opacity region. It is true that some of the stars are in the bordering region of high opacity. In Equation (1), interstellar extinction is taken care with A_V = N.d/(2.21 × 10²¹). We tried to change N so that (M_V – M_V0 ) reduces below 5. The values of N thus obtained seem extremely unrealistic. The star HIP64871, which is at a high galactic latitude, where we expect low interstellar extinction, needs to have N = 2 cm⁻³ to bring the deviation in (M_V – M_V0 ) below 5. For the stars HIP87083, HIP87092, and HIP87345 which are towards the galactic centre, the value of N required is 3 cm⁻³, 10 cm⁻³, and 45 cm⁻³, respectively. These numbers are totally unrealistic. It is therefore clear that the reason for abnormality in magnitudes is not due to any abnormal extinction. It is most probably due to incorrect MK classification of these stars which is in use presently (misidentification of stars can be a very likely reason for such wrong classifications).

Figure 5. This figure shows the position of the stars with |M_V – M_V0 | ≥ 5 mag. (Table 2) in our Galaxy. It is clear from this figure that the stars are well scattered throughout the galactic sphere and do not belong to any particular dark region.

Figure 6. The stars from Figure 5 are over-plotted on integrated opacity derived by Vergely et al. (Reference Vergely, Valette, Lallement and Raimond2010) for a line of site distance of 250 pc. The plot is in galactic co-ordinates in Aitoff projection. The positions of the stars do not show any correlation with the high opacity regions. Credit: Vergely J.-L., Valette B., Lallement R. & Raimond S., A&A, 518, A31, 2010, reproduced with permission © ESO.

Since a complete MK spectral classification (i.e., spectral type and luminosity) is a morphological description of the spectrum, it is independent of Hipparcos distances. However, it does often correlate with them (Garrison Reference Garrison2002). Therefore some luminosity classes, such as those arising from high microturbulence in the F-type stars, may not be wrong. However, the differences from microturbulence are within the ±2 mag, which is well within the working limit of this work.