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Download lecture 1 - University of Florida Astronomy
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Transcript
Daily Motions • Sun: Daily Motions • Stars: – stars travel on arcs in the sky moving from east to west. – some stars rise and set – others do not and are circumpolar – due to Rotation of Earth • 23 hour 56 min – rises in the east – sets in the west – travels on an arc across the sky – 24 hours Solar Day = 24 hours Solar and Sidereal Days Why is the Solar Day longer than the Sidereal Day? Sidereal Day = 23 hours 56 min Annual Motions of the Sun • The altitude of the Sun changes with season – It reaches a maximum on the summer solstice (June 21 in the northern hemisphere) – Its minimum altitude is reached on the winter solstice (December 21 in the northern hemisphere) • The sunrise and sunset points along the horizon also change with season – It rises and sets due east on the equinox (Sep 21, and March 21) – It rises north of east in the summer south of east in the winter Annual Motion of the Stars Coordinate system on Earth • Every day a given star or constellation rises and sets 4 minutes earlier with respect to the Sun • Therefore after one year it returns to the same position relative to the Sun Gainesville: 29.6510N, 82.3250W 1 Celestial Sphere • You can imagine that the stars and sun are attached to the surface of a great sphere • The earth appears to be at the center of the sphere • The sphere rotates from east to west on an axis that points to the north celestial pole • To explain the daily motions of the sky you can imagine the sphere rotating once in 23 hours 56 minutes Where are we? • The position of a celestial pole near the horizon, tells us we must be near the Equator. Also consider the angles the star trails make with the horizon: 90 degrees. Parts of the Celestial Sphere • Celestial pole - extends from the rotation axis of the earth – all stars appear to rotate about this point – some stars are circumpolar – some stars rise & set • Celestial equator - extends from the earth’s equator • Your latitude on earth determines the angle at which stars will rise & set with respect to your local horizon Question • You are kidnapped, drugged and placed in a dark room for an indefinite period of time! • You escape and find a radio to call for help but you don’t know where you are! • Luckily, it’s a clear night. You watch the stars for while and you see the stars rising at a 20 degree angle with respect to your horizon. • What can you tell your rescuers about your location? 2 Annual Motion of Sun • The sun moves along a repeatable path on the celestial sphere throughout the year. This path is called the ECLIPTIC – Sun moves east ward relative to stars on celestial sphere – It moves 360 degrees in a year about 1 degree per day – The constellations through which we see the sun move are the constellations of the ZODIAC • This apparent motion is due to the Earth orbiting the Sun Annual Motions of the Stars Annual Motions of the Stars • The constellations that are visible on a given night are those opposite from the Sun on the celestial sphere • Thus you see different stars at different times of the year as the Sun moves along the ecliptic relative to the stars • The apparent motion is due to the Earth orbiting the Sun Coordinate system on Earth Gainesville: 29.6510N, 82.3250W Coordinate Systems • Altitude : angular distance above horizon • Azimuth : angular distance measured along horizon to location of object • By convention azimuth is measured from the north going eastward • Advantages • Disadvantages Equatorial Coordinate System Declination – the angular distance of a star along a circle north or south of celestial equator (degrees:arcmin:arcsec) Right Ascension – the angular distance of a object measured eastward from the vernal equinox along the celestial equator (H:M:S) 3 Seasons • With the annual motion of the Earth around the Sun, we notice a cyclic pattern in the weather, known as the seasons. • Observations: – Seasons are reversed in the Northern and Southern Hemispheres • For example, you’re at the beach at Cape Cod in July, they’re skiing in New Zealand! – The region near the equator is hottest; poles are the coldest – The Sun’s position in the sky changes Reason for Seasons: Distance? • Predictions: Reasons for the Seasons? • What causes this pattern? • Two Possible Models: – Distance of the Earth from the Sun? – Tilt of the Earth’s axis with respect to the Earth’s orbital plane (ecliptic) Reason for Seasons: Distance? • Observations: – Relation between Earth-Sun distance and season • for example, the Earth should be closest to the Sun in summer – Same season every where on Earth • since the Earth is tiny compared to the EarthSun distance Reason for Seasons: Distance? • Predictions don’t match Observations: – Seasons are reversed in the Northern and Southern Hemispheres • For example, you’re at the beach at Cape Cod in July, they’re skiing in New Zealand! Reason for the Seasons: Tilt? • The Earth’s axis of rotation is tilted by 23.5 degrees with respect to the ecliptic pole • As the Earth moves around the Sun, the Earth’s north pole points to a fixed position in space – The Earth is closest to the Sun during northern winter 4 Reason for the Seasons: Tilt? • Predictions: – Summer occurs in hemisphere pointed toward the Sun – Winter occurs in the hemisphere pointed away from the Sun – Therefore: Seasons are reversed in northern and southern hemisphere Reason for the Seasons: Tilt • The angle at which the Sun’s rays strike the surface of the Earth is closer to a right angle (90 degrees) in the summer • Therefore the Earth’s surface intercepts more rays of Sunlight and hence more energy • This is the main reason that it is warmer in the summer Reason for the Seasons: Tilt • Predictions match observations: – The northern hemisphere and southern hemisphere seasons are reversed – The region near the equator is hottest; poles are coldest Reason for the Seasons: Tilt • It’s warmer in the summer and colder in the winter for two reasons: – the Sun is higher in the sky in the summer – the days are longer – the Sun reaches it’s highest point in the sky on the summer solstice (June 21 in northern hemisphere) Reason for the Seasons • Demonstration Question • When is the hottest time of year in Quito Ecuador? • If the Earth’s rotation axis was perpendicular to it’s orbital plane (ecliptic), what would you expect the seasons to be like? • If the Earth’s rotation axis was parallel to it’s orbital plane (ecliptic), what daily and annual effects would this have? 5 Temperature in Ecuador Gainesville: 29.6510N, 82.3250W What is special about the Tropics (i.e. between +23.5degrees and -23.5 degrees latitude)? Assignment Reference Reading – Astronomy & Astrophysics by Zelik and Gregory - chapter 1, chapter 3, chapter 4-1 & 4-2 The Physical Universe, An Introduction to Astronomy by Shu 6
