our solar system chapter 29. overview of our solar system the earth is one of eight (8) planets that...
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OUR SOLAR SYSTEM
Chapter 29
Overview of our Solar System
The Earth is one of eight (8) planets that orbit the Sun
All planets, as well as their moons, orbit in the same direction
All planets lie near the same plane
Each of our planets have various sizes, surface conditions, and internal structures
Earth Centered ModelEarly ideas about the solar system were
developed solely on the basis of Earth-based observations of the sky1. Early astronomers assumed the Sun,
planets, and stars orbited a stationary Earth
2. Problem: some aspects of planetary motion were difficult to explain1. For instance, occasionally a planet would move in the
opposite direction across the sky, retrograde motion2. Retrograde motion caused astronomers to continue
searching for a better model of our solar system
The Heliocentric ModelNicolaus Copernicus suggested
the Sun to be the center of the solar system in 1543.◦Suggests that the Earth and other
planets orbit a stationary Sun.◦Provided a simple explanation for
retrograde motion, noting that the inner planets move faster so when they bypass the slower-moving outer planets it appears that the outer planets are moving backward
KEPLER’S FIRST LAW Johannes Kepler demonstrated that each planet orbits the
Sun in a shape called an ellipse, rather than a circleAn ellipse is an oval shape that is centered on two, rather
than one, pointsThe two points are called the fociEach planet’s elliptical orbit is a different shape and size,
with the Sun always being at one focusAverage distance from the Sun is measured in
astronomical unitsThe major axis is the line that goes between the two foci
EccentricityA planet in an elliptical orbit is not at a
constant distance from the Sun
When a planet is closest to the Sun in its orbit it is said to be at perihelion
When a planet is furthest from the Sun in its orbit it is said to be at aphelion
The length of time it takes a planet or other body to travel a complete elliptical orbit around the Sun is referred to as the orbital period
KEPLER’S SECOND AND THIRD LAWS
• Kepler’s second law states that an imaginary line between the Sun and a planet sweeps out equal amounts of area in equal amounts of time.
• Kepler derived a mathematical relationship between the size of a planet’s ellipse and its orbital period. He found that the square of the orbital period (P) equals the cube of the semi-major axis of the orbital ellipse (a).
• This mathematical relationship (P2 = a3) is Kepler’s third law. (P refers to a unit of time measured in Earth years and a is a unit of length measured in astronomical units.)
Law of Universal GravitationIsaac Newton developed an understanding
of gravity by observing the Moon’s motion, the orbits of the planets, and the acceleration of falling objects on Earth
Newton’s statement of the relationship among the masses of two bodies and the force and distance between them is known as the Law of Universal Gravitation
This law is stated as follows:◦Every pair of bodies in the universe attract each
other with a force that is proportional to the product of their masses and inversely proportional to the square of the distance between them
The Terrestrial PlanetsThe inner four planets
Close to the size of Earth
Each have rocky, solid surfaces
Mercury, Venus, Earth, and Mars
Mercury
•Closest planet to the Sun•No moons•Approximately 1/3 the size of Earth•In 2 of Mercury’s years, 3 of Mercury’s days have passed•Essentially no atmosphere but what does exist is composed of primarily oxygen and sodium•Largest day / night temperature difference (427 C daytime / -173 C at night)•Surface is covered with craters and plains with a planet-wide system of cliffs•Extensive nickel-iron core, making up approximately 2/3 of the planet
Venus
Second planet from the Sun No moons, highest albedo of all
planets Thick clouds in atmosphere,
composed of sulfuric acid Extremely hot on surface One day is 243 Earth days in length
(slow rotation) Retrograde rotation (day is longer
than year) Atmosphere is primarily carbon
dioxide and nitrogen Greenhouse Effect causes Venus to
be the hottest planet (although it is not closest to the Sun)
Surface has been smoothed by volcanic lava flows, only a few impact craters
Surface is relatively young with little evidence of tectonic activity
Internal structure is similar to Earth. Considered to be Earth’s “twin”
EarthThird planet from SunUnique properties in
comparison to other planets
Water exists in all three states (solid, liquid, and gas)
Life is abundant on EarthModerately dense
atmosphere comprised primarily of nitrogen and oxygen
Axis is tilted, which causes seasonal changes
Wobble in rotation on axis, called precession
Only has one moon
Mars
Fourth planet from Sun, outermost terrestrial planet
Often referred to as Red Planet, which is caused by a high iron content in the soil
Smaller, less dense than Earth. Has 2 irregularly-shaped moons – Phobos and Deimos
Atmosphere is thin and turbulent, constant wind and dust storms
Southern hemisphere is heavily cratered and northern hemisphere is dominated by plains
Four gigantic shield volcanoes, largest is Olympus Mons. (Also largest mountain in solar system)
Martian surfaces suggest that liquid water once existed on the surface as there are dried river and lake beds present
Polar ice caps on both poles Hypothesize that the core of Mars is iron
and nickel, possibly mixed with sulfur. Mars has no active magnetic field, but it is believed that the core is solid
There is no evidence of tectonic activity on the surface or crust of Mars
The Gas Giant PlanetsRemaining planets in solar
system
Larger than Earth in size
Gaseous, lack solid surface
Jupiter, Saturn, Uranus, and Neptune
Jupiter Largest planet, 11 times larger than
Earth, fifth from Sun Banded appearance, due to a result of
flow patterns in the atmosphere Four major satellites, composed of ice
and rock mixtures. 63 total moons at last count!
Low density, atmosphere is made up mostly of hydrogen and helium – which exist in a liquid form
Magnetic field is present Rotation is rapid, spinning on axis in a
little less than 10 hours, making shortest day in solar system
Belts (low, warm, dark-colored clouds that sink) and zones (high, cool, light-colored clouds that rise) are present throughout Jupiter
Great Red Spot – atmospheric storm that has been rotating around Jupiter for more than 300 years, it is 5 TIMES the diameter of Earth
Discovery of one large ring, 6400km wide, that first proved Saturn is not the only gas giant with rings
Jupiter’s Main Moons: Io, Europa, Ganymede, and Callisto
Saturn
•Sixth planet from Sun, second largest in solar system•Density is lower than that of water•Rotates rapidly for its size, has several zones and belts (as Jupiter)•Atmosphere is dominated by hydrogen and helium, also contains ammonia ice•Internal structure is likely fluid, with solid core and strong magnetic field•Most intricate ring system in solar system. Rings are composed of rocks and ice that ranges from microscopic to the size of an average house!!•Many satellites, including its largest moon, Titan, which is the second largest in the solar system•Titan is larger than Earth’s moon and its atmosphere is made of nitrogen and methane
URANUS•Seventh planet from the Sun•Discovered accidentally in 1781•Titania and Oberon are two of larger moons; however, there are several that orbit Uranus’ equatorial plane•Exact moon count is constantly changing, last known to be 27•Dark, black rings•4 times as large and 15 times as massive as Earth•Atmospheric composition causes a blue, velvety appearance •Methane gas reflects blue light back into space although most of the atmosphere is composed of hydrogen and helium•Very few clouds present on Uranus and they are difficult to detect due to their similar brightness and color to the surrounding atmosphere•No distinct zones or belts like those observed on Jupiter and Saturn•Internal structure is similar to Jupiter – it is completely fluid with exception to a small, solid core•Strong magnetic field•Rotational axis is tipped so far that the North Pole nearly lies in its orbital plane•It is believed that Uranus was knocked on its side by a massive collision with a passing object
Neptune
• Discovered in 1846
• Smaller and more dense than Uranus, but four times as large as Earth
• Bluish color caused by methane in the atmosphere, although methane absorbs red light
• Distinctive clouds and atmospheric belts and zones similar to Jupiter and Saturn
• Had a persistent storm (The Great Dark Spot) that disappeared in 1994. The storm was allegedly caused by wind shear in the methane rich atmosphere
• Many moons, 13, with the largest being Triton
• Triton has a retrograde orbit and a thin atmosphere with nitrogen geysers
• Six faint rings composed of microscopic-sized dust particles
In 2003, U.S. astronomer Mike Brown discovered a new object, in which he named Eris, beyond Pluto.
The discovery caused astronomers to talk about what makes a planet a "planet”
It was determined that Pluto and objects like it were not really planets due to their size and location in the solar system and that they were instead called dwarf planets
Dwarf planets are also called plutoids, which are located further out in space than Neptune
CURRENT PLUTOIDS
Formation of our Solar SystemWe use Earth based observations
and data from probes to derive theories about how our solar system formed
Significant observations include the shape of our solar system, the differences among the planets, and the oldest planetary surfaces, asteroids, meteorites, and comets
A Collapsing Interstellar CloudStars and planets form from clouds of gas and
dust, called interstellar cloudsInterstellar clouds consist primarily of helium
and hydrogenThey often appear as blotches of light and dark
spots, due to the dust particles being partially illuminated by the reflection from stars
The density of an interstellar cloud is very low (due to gas content) but they can start to condense due to gravity.
The cloud then becomes concentrated enough to form a star and possibly planets.
Astronomers agree that our solar system began this way.
ORION’S NEBULA IS ONE OF THE MOST BRIGHT AND BEAUTIFUL INTERSTELLAR CLOUDS VISIBLE TO THE NAKED EYE WITHIN THE NIGHT SKY
Sun and Planet Formation
The disk of dust and gas that formed the Sun and planets is called a solar nebula
The condensed concentration at the center eventually became the Sun
As the condensing slowed, tiny bits of condensed materials accumulated and merged together to form larger bodies called planetesimals.
Further growth of planetesimals continued, through mergers and collisions, sometimes destroying them and making smaller bodies (still relatively large) we now call planets
Order of Formation In the outer solar system, the first large planet to develop
was Jupiter. As Jupiter increased in size through the merger of icy planetesimals, gravity began to attract additional gas, dust, and planetesimals… making it grow even larger.
Saturn and other gas giants then formed in similar patterns, but could not grow as large because Jupiter had collected so much material in the vicinity.
As each gas giant gathered material from its surroundings, a disk formed within the equatorial plane – much like that of the early solar system – which then formed satellites
Inner planets then began forming in the same fashion; however, the gravitational pull of the Sun swept up much of the gas in the area and prevented them from acquiring much additional materials. This is believed to be the reasoning why they are so much smaller in size than the gas giants.
The Asteroid
Belt
Thousands of bodies that orbit the Sun within the planetary orbit are called asteroids
Range in size from a few km to about 1000 km in diameter
Pitted, irregular surfaces Most are located in the asteroid belt,
between Mars and Jupiter Asteroids are thought to be leftover
planetesimal pieces from the time of the solar system’s formation
As they orbit, they occasionally collide and cause broken fragments to fall toward other planets (such as Earth)
When interplanetary material falls toward Earth and enters Earth’s atmosphere it is called a meteoroid
When the meteoroid falls toward Earth but burns up in the atmosphere it is called a meteor
If the meteoroid does not completely burn up and part of it collides with the ground it is called a meteorite
Comets Small, icy bodies that have
highly eccentric orbits around the Sun
Made of ice and rock, ranging from 1 to 10km in diameter
Head of comet is called the coma and the center, solid core is called the nucleus
Sometimes, a comet intersects with Earth and a meteor shower occurs as result of particles burning up upon entering the Earth’s atmosphere
Two clusters, or clouds, of comets:1. Kuiper Belt – close to Pluto,
30-50 AU from the Sun2. Oort Cloud – more than
100,000AU from the Sun