A complete sample of blue horizontal branch (BHB) stars in the magnitude range 13.0 less than or equal to V less than or equal to 16.5 is isolated in two Galactic fields that have previously been searched for RR Lyrae variables: SB 57 in the Northern Polar Cap and the Lick Astrograph field RR 7 in the Anticenter (l=183 degrees, b=+37 degrees). These BHB stars are a subset of the AF stars found in the Case Low-Dispersion Northern Survey; lists of these AF stars were made available by the late Nick Sanduleak. The completeness of the sample was confirmed by reference to the photometric survey of SA 57 by Stobie gr Ishida [AJ, 93, 624 (1987)] that is complete to fainter than V=18. In the color range 0.00 less than or equal to (B-V)(0) less than or equal to +0.20, we can distinguish the BHB stars among these AF stars by comparing them both with well known local field horizontal branch (FHB) stars and also the BHB members of the halo globular clusters M3 and M92. The criteria for this comparison include (1) a (u-B)(K) color index (derived from photoelectric observations using the Stromgren It filter and the Johnson B and V filters) that measures the size of the Balmer jump, (2) a spectrophotometric index Lambda that measures the steepness of the Balmer jump, and (3) a parameter D-0.2 that is the mean width of the H delta and H gamma Balmer lines measured at 20 percent of the continuum level. These criteria give consistent results in separating BHB stars from higher gravity main sequence AF stars in the color range 0.00 less than or equal to (B-V)(0) less than or equal to +0.20. All three photometric and spectrophotometric criteria were measured for 35 stars in the SA 57 field and 37 stars in the RR 7 field that are in the color range (B-V)(0) less than or equal to +0.23 and in the magnitude range 13.0 less than or equal to V less than or equal to 16.5. For a small number of additional stars only (U-B)(K) was obtained. Among the AF stars that are fainter than B=13 and bluer than (B-V)(0)=+0.23, about half of those in the SA 57 field and about one third of those in the lower latitude RR 7 held are BHB stars. Isoabundance contours were located empirically in plots of the pseudoequivalent width versus (B-V)(0) for the lines of Mg II lambda 4481 Angstrom, Ca II lambda 3933 Angstrom and Fe I lambda 4272 Angstrom. Solar abundances were defined by the data from main sequence stars in the Pleiades and Coma open clusters. Data from the BHB stars in M3 and M92 defined the [Fe/H]=-1.5 and -2.2 isoabundance contours, respectively. Metallicities of all stars were estimated by interpolating the measured pseudoequivalent widths in these diagrams at the observed (B-V)(0). The distribution of [Fe/H] found for the BHB stars in this way is very similar to that which we found for the RR Lyrae stars in the same fields using the Preston Delta S method. The space densities of these BHB stars were analyzed both separately and together with earlier observations of field BHB stars given by Arnold and Gilmore [MNRAS, 257, 225 (1992)], Sommer-Larsen and Christensen [MNRAS, 219, 537 (1986)], and Preston er al. [ApJ, 375, 121 (1991a)]. This analysis supports a two-component model for the halo of our Galaxy that is similar in many respects to that proposed by Hartwick [The Galaxy (Reidel, Dordrecht) (1987)] although our discussion refers only to the region outside the solar circle. For Z less than or equal to 5 kpc, a classical spherical halo dominates which follows a R(gal)(-3.5) space-density law and which has a HB morphology like that of the globular cluster M3 gal (i.e., approximately equal numbers of BHB and RR Lyrae stars). Closer to the galactic plane, there is an additional component with a much flatter galactic distribution (scale height similar to 2.2 kpc near the Sun). The stars of the two components do not have significantly different metallicity distributions but do have slightly different distributions of the Lambda parameter which measures the steepness of the Balmer jump; this is the only physical criterion (independent of spatial or kinematic considerations) which distinguishes between the two components. If present estimates of the local RR Lyrae star space density are correct, then the ratio of BHB stars to RR Lyrae stars is higher in the flatter halo component. The flat component would then have a bluer HB morphology (which could be interpreted as making it older) than the spherical component. In the solar neighborhood about 80 percent of the BHB stars come from the flat component and about 20 percent from the spherical component. More than half of the AF stars with V greater than or equal to 13.0 and (B-V)(0) less than or equal to +0.23 are not BHB stars but have surface gravities that are more like those expected for main sequence stars. Their measured metallicities lie in the range -0.2 less than or equal to [Fe/H] less than or equal to -2.3. The more metal-poor of these stars are probably similar to the blue metal-poor stars that have been discussed by Preston et al. [AJ, 108, 538 (1994)] which, while they probably include globular cluster blue stragglers as a subset, must also comprise stars of other types.
