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2: Celestial Sphere

  • Page ID
    108931
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    • 2.1: Thinking Ahead
    • 2.2: The Sun and the Moon
      This page discusses the movement of the Sun, Moon, and planets along the Ecliptic on the Celestial Sphere and introduces the Zodiac, consisting of 12 constellations plus one additional. It explains that astronomers measure sizes and distances in angular measurements, noting that the Sun and Moon appear to span approximately ½ degree or 30 arcminutes from Earth's view, despite their actual sizes being different.
    • 2.3: The Sky Above
      The direct evidence of our senses supports a geocentric perspective, with the celestial sphere pivoting on the celestial poles and rotating about a stationary Earth. We see only half of this sphere at one time, limited by the horizon; the point directly overhead is our zenith. The Sun’s annual path on the celestial sphere is the ecliptic—a line that runs through the center of the zodiac, which is the 18-degree-wide strip of the sky within which we always find the Moon and planets.
    • 2.4: Eclipses of the Sun and Moon
      The Sun and Moon have nearly the same angular size (about 1/2°). A solar eclipse occurs when the Moon moves between the Sun and Earth, casting its shadow on a part of Earth’s surface. If the eclipse is total, the light from the bright disk of the Sun is completely blocked, and the solar atmosphere (the corona) comes into view. Solar eclipses take place rarely in any one location, but they are among the most spectacular sights in nature. A lunar eclipse takes place when the Moon moves into Earth’
    • 2.5: Astrology and Astronomy
      The ancient religion of astrology, with its main contribution to civilization a heightened interest in the heavens, began in Babylonia. It reached its peak in the Greco-Roman world, especially as recorded in the Tetrabiblos of Ptolemy. Natal astrology is based on the assumption that the positions of the planets at the time of our birth, as described by a horoscope, determine our future. However, modern tests clearly show that there is no evidence for this, even in a broad statistical sense.
    • 2.6: The Birth of Modern Astronomy
      Nicolaus Copernicus introduced the heliocentric cosmology to Renaissance Europe in his book De Revolutionibus. Although he retained the Aristotelian idea of uniform circular motion, Copernicus suggested that Earth is a planet and that the planets all circle about the Sun, dethroning Earth from its position at the center of the universe. Galileo was the father of both modern experimental physics and telescopic astronomy.
    • 2.7: Stellar and Celestial Object Brightness
      This page explains the distinction between luminosity and apparent brightness in stars. Luminosity, measured in watts, indicates a star's total power output, using the Sun as a reference (3.846×10^26 watts). Apparent brightness, on the other hand, is the light received per unit area, which decreases with distance according to the Inverse Square Law. The summary highlights that as one moves away from a light source, such as while driving at night, the perceived brightness diminishes significantly.
    • 2.8: Magnitude System
      This page explains the magnitude system of ranking stars by brightness, initiated by Hipparchus and later revised by Pogson. It establishes a scale from 1 (brightest) to 6 (faintest), with Polaris rated at 2. Pogson's 1856 revisions quantified brightness differences and included the Sun and Moon, introducing the concept of Apparent Magnitude (M v) for measuring how celestial objects appear from Earth.
    • 2.9: The Magnitude Scale
      One of the most fundamental properties of a star is its brightness. Astronomers measure stellar brightness in units called magnitudes, which seem at first counterintuitive and confusing.
    • 2.10: Exercises


    2: Celestial Sphere is shared under a not declared license and was authored, remixed, and/or curated by LibreTexts.

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