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تسجيل مستخدم جديدMetallicity Calibration and Photometric Parallax Estimation: II. SDSS photometry
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We used the updated [Fe/H] abundances of 168 F-G type dwarfs and calibrated them to a third order polynomial in terms of reduced ultraviolet excess, $delta_{0.41}$ defined with $ugr$ data in the SDSS. We estimated the $M_g$ absolute magnitudes for the same stars via the re-reduced Hipparcos parallaxes and calibrated the absolute magnitude offsets, $Delta M_g$, relative to the intrinsic sequence of Hyades to a third order polynomial in terms of $delta_{0.41}$. The ranges of the calibrations are $-2<$[Fe/H]$leq$0.3 dex and $4<M_gleq6$ mag. The mean of the residuals and the corresponding standard deviation for the metallicity calibration are 0 and 0.137 mag; while, for the absolute magnitude calibration they are 0 and 0.179 mag, respectively. We applied our procedures to 23,414 dwarf stars in the Galactic field with the Galactic coordinates $85^{circ}leq bleq90^{circ}$, $0^{circ}leq lleq360^{circ}$ and size 78 deg$^{2}$. We estimated absolute magnitude $M_g$ dependent vertical metallicity gradients as a function of vertical distance $Z$. The gradients are deep in the range of $0<Zleq5$ kpc, while they are very small positive numbers beyond $Z=5$ kpc. All dwarfs with $5<M_gleq6$ mag are thin-disc stars and their distribution shows a mode at $(g-r)_0approx 0.38$ mag, while the absolute magnitudes $4<M_gleq5$ are dominated by thick disc and halo stars, i.e. the apparently bright ones ($g_0leq18$ mag) are thick-disc stars with a mode at $(g-r)_0sim0.38$ mag, while the halo population is significant in the faint stars ($g_0>18$ mag).
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We present metallicity and photometric parallax calibrations for the F and G type dwarfs with photometric, astrometric and spectroscopic data. The sample consists of 168 dwarf stars covering the colour, iron abundance and absolute magnitude intervals
$0.30<(B-V)_0<0.68$ mag, $-2.0<[Fe/H]<0.4$ dex and $3.4<M_V<6.0$ mag, respectively. The means and standard deviations of the metallicity and absolute magnitude residuals are small, i.e. $langleDelta[Fe/H]_{res}rangle=0$ and $sigma=0.134$ dex, and $langleDelta (M_V)_{res}rangle=0$ and $sigma=0.174$ mag, respectively, which indicate accurate metallicity and photometric parallax estimations.
We present the calibration of the [$alpha/$Fe] element in terms of ultra-violet excess for 465 dwarf stars with spectral type F0-K2. We used a single calibration, fitted to a third degree polynomial with a square of the correlation coefficient 0.74 a
nd standard deviation 0.05 mag, for all stars due to their small colour range, $0.1<(g-r)_0leq 0.6$ mag, and high frequency in the blueward of the spectrum which minimize the guillotine effect. Our calibration provides [$alpha/$Fe] elements in the range $(-0.05, 0.35]$ dex. We applied the procedure to a high-latitude field, $85^circ leq b leq 90^circ$ with size 78 deg$^2$ and we could estimate the [$alpha/$Fe] elements of 23,414 dwarf stars which occupy a Galactic region up to a vertical distance of $z=9$ kpc. We could detect a small positive gradient, $d[alpha/{rm Fe}]/dz=+0.032 pm0.002$ dex kpc$^{-1}$, for the range $0<z<5$ kpc, while the distribution of the [$alpha/$Fe] element is flat for further $z$ distances.
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