Explanation: Regulus is indeed the brightest object in the constellation Leo, and the source explicitly states it is 'recognized as one of the brightest stars visible in the night sky,' with an apparent magnitude of +1.35, making it the twenty-first brightest star.

Explanation: While the Bayer designation Alpha Leonis is correct, it signifies Regulus as the *brightest* star in the Leo constellation, not the second brightest. The Bayer designation typically assigns Greek letters in order of decreasing brightness.

Explanation: The source explicitly states that the Regulus system is located approximately 79 light-years from our Solar System.

Explanation: The traditional name 'Regulus' is derived from *Latin*, meaning 'prince' or 'little king,' not Greek for 'great king'.

Explanation: The International Astronomical Union (IAU) organized a Working Group on Star Names (WGSN) in 2016, and 'Regulus' was among the first names approved and standardized.

Explanation: In Chinese astronomy, Regulus is known as the *Fourteenth* Star of Xuanyuan, the Yellow Emperor, not the First Star.

Explanation: The source confirms that the Babylonians called Regulus 'Sharru,' meaning 'the King,' and it indeed marked the 15th ecliptic constellation.

Explanation: The overall apparent magnitude of the Regulus system is +1.35, not +8.1. Furthermore, the light output of the system is predominantly from Regulus A, not Regulus B.

Explanation: Regulus is best observed in the northern hemisphere during late winter and spring evenings, and it is obscured by the Sun's glare during late summer (August 22-24).

Explanation: The heliacal rising of Regulus typically occurs late in the first week of September or in the second week, not late August. Late August is when it is obscured by the Sun.

Explanation: Regulus is identified as the brightest object in the constellation Leo.

Explanation: The Regulus system is located approximately 79 light-years from our Solar System.

Explanation: The full Bayer designation for Regulus is Alpha Leonis.

Explanation: The traditional name 'Regulus' is derived from Latin, meaning 'prince' or 'little king'.

Explanation: The Babylonians referred to Regulus as 'Sharru,' which means 'the King'.

Explanation: The Arabic name 'Qalb al-Asad' for Regulus translates to 'the heart of the lion'.

Explanation: In Persia, Regulus was known as 'Miyan,' meaning 'the Centre'.

Explanation: The Regulus system has an overall apparent magnitude of +1.35, making it the twenty-first brightest star in the night sky.

Explanation: The IAU's Working Group on Star Names (WGSN) was organized to catalog and standardize proper names for stars.

Explanation: A light-year is defined as the distance light travels in one Earth year.

Explanation: Regulus is best observed in the evening during the northern hemisphere's late winter and spring.

Explanation: The source clarifies that while Regulus appears as a single star, it is actually a *quadruple* star system, composed of four stars organized into two distinct pairs.

Explanation: The spectroscopic binary Regulus A consists of a blue-white main-sequence star and a *pre-white dwarf* companion, not a red dwarf. Red dwarfs are components of the Regulus BC pair.

Explanation: While the angular separation of 177 arc-seconds is correct, this distance makes the Regulus BC pair visible in *amateur* telescopes, not exclusively professional ones.

Explanation: Regulus Ab has a mass of 0.31 ± 0.10 solar masses, which is indeed consistent with its classification as a pre-white dwarf.

Explanation: The spectroscopic binary Regulus A consists of a blue-white main-sequence star and a pre-white dwarf companion.

Explanation: Regulus Ab has a temperature of 20,000 ± 4,000 Kelvin.

Explanation: Regulus Ab has a radius of 0.061 ± 0.011 solar radii.

Explanation: The source defines a blue straggler as a star that appears hotter and bluer than other co-formed stars in its cluster, which is consistent with the classification of Regulus A.

Explanation: The spectral type of Regulus A is B8 IVn, not M4 V. M4 V is the spectral type for Regulus C, which is a red dwarf.

Explanation: Regulus A has negative U-B (-0.36) and B-V (-0.11) color indices, which are characteristic of hotter stars. Positive values are associated with cooler temperatures, as seen in Regulus BC.

Explanation: Regulus A is *suspected* to be a variable star, but it is not stated to be a *confirmed* variable star with significantly fluctuating brightness.

Explanation: Regulus A's equatorial radius (4.21 solar radii) is indeed larger than its polar radius (3.22 solar radii), a direct consequence of its rapid rotation causing an oblate shape.

Explanation: Gravity darkening causes the *poles* of Regulus A to be considerably hotter and five times brighter per unit surface area than its equatorial region, not the other way around.

Explanation: The source confirms that Regulus A emits polarized light due to its extremely rapid rotation, which results in a highly oblate (flattened) shape.

Explanation: Regulus A is classified as a blue straggler.

Explanation: The spectral type of Regulus A is B8 IVn.

Explanation: Regulus A has an equatorial radius of 4.21 solar radii.

Explanation: The surface gravity (log g) of Regulus A is 3.54 ± 0.09 cgs.

Explanation: The primary star of Regulus A has a rotation period of only 15.9 hours.

Explanation: The phenomenon where Regulus A's poles are hotter and brighter per unit surface area than its equatorial region is known as gravity darkening.

Explanation: Regulus A has an equatorial temperature of 11,010 Kelvin.

Explanation: The metallicity [Fe/H] of Regulus A is +0.21 dex.

Explanation: Regulus C has an apparent magnitude of +13.5, making it the faintest directly observed star in the system and necessitating a substantial telescope for its observation.

Explanation: The source confirms that the Regulus BC pair is in the main sequence evolutionary stage, which is characterized by actively fusing hydrogen into helium in their cores.

Explanation: The source explicitly states that Regulus B has a spectral type of K2 V (orange dwarf) and Regulus C has a spectral type of M4 V (red dwarf).

Explanation: Regulus B has an apparent magnitude of +8.1, making it visible with binoculars.

Explanation: Regulus B has a spectral type of K2 V, and Regulus C has a spectral type of M4 V.

Explanation: Regulus B has a luminosity of 0.322 ± 0.005 solar luminosities.

Explanation: Regulus B has a temperature of 4,968 Kelvin.

Explanation: The metallicity [Fe/H] of Regulus B is -0.21 dex.

Explanation: The radial velocity of Regulus A is indeed 4.39 ± 0.09 kilometers per second. A positive radial velocity value indicates that the star is moving away from the observer.

Explanation: The source provides the proper motion values for Regulus A as -248.73 ± 0.35 milliarcseconds per year in Right Ascension and 5.59 ± 0.21 milliarcseconds per year in Declination.

Explanation: Regulus A has an absolute magnitude of -0.57, and absolute magnitude is indeed a measure of a star's intrinsic brightness, standardized to a distance of 10 parsecs.

Explanation: The orbital period of 40.102 days is correct, but this relatively short period indicates a *close* binary system, not a very wide one.

Explanation: The eccentricity of the orbit for Regulus Aa and Ab is assumed to be 0, indicating a *perfectly circular* orbit, not 1, which would imply a parabolic or highly elongated orbit.

Explanation: Regulus A exhibits a proper motion of -248.73 ± 0.35 milliarcseconds per year in Right Ascension.

Explanation: Regulus A has an absolute magnitude of -0.57.

Explanation: The orbital period of Regulus Aa and Ab is approximately 40.102 days.

Explanation: The eccentricity of the orbit for Regulus Aa and Ab is assumed to be 0, indicating a perfectly circular orbit.

Explanation: The semi-major axis of the orbit for Regulus Aa and Ab is 74 solar radii.

Explanation: The source explicitly states that Regulus is located 0.465 degrees from the ecliptic, making it the closest bright star to this plane.

Explanation: While Regulus's proximity to the ecliptic does cause frequent lunar occultations, they occur in 'spates' approximately every 9.3 years, not annually.

Explanation: The last planetary occultation of Regulus occurred on July 7, 1959, but it was by *Venus*, not Mars.

Explanation: The source confirms that during the 2005 occultation by asteroid 166 Rhodope, measurements of differential light bending were indeed consistent with the predictions of general relativity.

Explanation: Regulus is located 0.465 degrees from the ecliptic, making it the closest bright star to this plane.

Explanation: Lunar occultations of Regulus occur in spates approximately every 9.3 years.

Explanation: The next predicted planetary occultation of Regulus will be by Venus on October 1, 2044.

Explanation: The 2005 occultation of Regulus by asteroid 166 Rhodope provided measurements of differential light bending that were consistent with general relativity.

Explanation: The initial age estimate for Regulus A was 50-100 million years. It was the presence of the white dwarf companion that suggested the system was *at least 1 billion years old*, implying it was much *older* than initially thought.

Explanation: The gravitational binding of SDSS J1007+1930 to Regulus is considered *uncertain* due to its extreme distance from the system, not definitive due to close proximity.

Explanation: The brown dwarf SDSS J1007+1930 is estimated to have a mass of roughly 60 Jupiter masses (0.06 solar masses) and a spectral type of L9 or T0.

Explanation: The gravitational binding of SDSS J1007+1930 to Regulus is uncertain primarily due to its *extreme distance* from the system. The source actually suggests its metal abundance is *similar* to Regulus B, which supports a potential binding, not disproves it.

Explanation: The presence of a white dwarf companion suggests the Regulus system is at least 1 billion years old, as this is the minimum time required for a white dwarf to form.

Explanation: SDSS J1007+1930 is estimated to have a mass of roughly 0.06 solar masses (60 Jupiter masses).

Explanation: SDSS J1007+1930 has a spectral type of L9 or T0.