Aust Curriculum Connections 2012

... tonight’s sky. The other planets: orbits and time for a “year”. What are the planets made of? Could I land on Jupiter? How many “years” old would I be if I lived on other planets? How long would it take to travel there? Why are some bodies covered in craters? Why not the Earth? The Southern Cross as ...

PISGAH Text by Dr. Bob Hayward ASTRONOMICAL Astronomer

... describes the timing of the five visible or “classical” planets in early June. The giant Jupiter leads the way and is high in the south at sunset. Lying just under the hind legs of the celestial king of the beasts, Leo the lion, Jupiter, the king of the planets, is the brightest object in the sky. I ...

PowerPoint. - teachearthscience.org

... location of the object (distance from the center of the planet). ...

hw4

... be determined by isolating certain spectral wavelength regions or by locating the peak wavelength. By making assumptions it is possible to estimate the radius and mass of a star from spectral characteristics. For example, giant stars have thinner spectral lines generally than small stars due to dens ...

Exoplanets

... Humans have always wondered if life exists elsewhere in the universe. Such life could take many forms, including some very different from our own, but because we only have information about Earth-life (carbon-based organisms) we may as well start by looking for life like us. This means we can test n ...

Part 2: Solar System Formation

... • Among these clouds the Hubble Space Telescope observed lumps and knots that appear to be new stars and planets being formed. ...

White Dwarf Stars Near The Earth

... the “ages” of the white dwarfs on this page, I mean how long they have been white dwarfs, not how long they were main-sequence stars before that.) 40 Eridani B is a member of a triple star system and was once the brightest and most massive of the three, since the other two are relatively cool K-clas ...

Earth and Space

... dust and gas), planets, and asteroids. It is approximately 100 light years in diameter. All objects in the Galaxy revolve around the Galaxy’s center. It takes the Sun 250 million years to pull us through 1 revolution around the center of the ...

Slide 1

... Tides are caused by the sun and moons gravitational pull, When the sun and moon are aligned, there are exceptionally strong gravitational forces, causing very high and very low tides which are called spring tides, though they have nothing to do with the season. When the sun and moon are not aligned, ...

Lecture 3 Ptolemy to Galileo

... Stars do not vary much in brightness over the course of a year. Stars do not show a large parallax over the course of a year. ...

Two Dissipating Exoplanet Atmospheres Taken from: Hubble

... This type of matter exchange is more commonly seen in close binary star systems. This is the first time it has been detected so clearly for a planet-star system. Shu-lin Li of Peking University, Beijing, first predicted that the planet’s surface would be distorted by its star’s gravity, and that gra ...

Test#4

... 18. The reason the Solar system does not have a lot of dust and gas between the planets is a) the solar wind blew the dust and gas out of the Solar system b) the planets accreted all the gas and dust c) the early Solar system was made up only of Hydrogen and Helium d) the Sun burns them up 19. All ...

August 2015 - Shasta Astronomy Club

... — cosmic realms where the night sky would appear ablaze with stars from the surface of a planet. The students, Richard Vo and Michael Sandoval, discovered the so-called ultracompact dwarf galaxies while sifting through opensource archives of astronomy observations by several different observatories ...

Astronomy 1020 Exam 1 Review Questions

... law? A star emits most of its light at 4000 Å, what is its temperature? If this star is 10 times bigger than the Sun, what is its luminosity with respect to the Sun? 11. What is more energetic, a blue or a red photon? How about an X-ray versus an infrared photon? Why do you say this? 12. Describe t ...

No Slide Title

... Kepler (NASA) ...

Lesson 37 questions – Gravitational Field - science

... M = 16π 2R3/GT2 M = (16π 2(0.5x1011)3)/((6.6710-11)86400002) ...

Planets - Cardinal Hayes High School

... • Planets – bodies that are partly solid or gaseous that orbit around the sun and are seen by reflected sunlight • Satellite – solid bodies that orbits planets (moons) ...

The HARPS search for southern extra-solar planets

... planet with a 4.7-d period (Bonfils et al. 2007). This recent example emphasizes that the interpretation of small-amplitude radial-velocity variations of M dwarfs needs care, since most are expected to be at least moderately active, and illustrates the value of chromospheric diagnostics and photomet ...

A105 Stars and Galaxies

... distance from the star. WHY? •The star needs to have the right mass. WHY? ...

Earth

... standard distance from Earth) from 20 pc. • Since the star will be “closer”, it will be brighter. • A brighter star has a smaller magnitude • Thus, we expect an absolute magnitude less than ...

Intelligent Life in the Milky Way Galaxy

...  No robotic probes orbiting Solar System  No Radio Signals from aliens, despite radio telescopes.  Some aliens will wander in the Galaxy, ...

Document

... One has to worry even about the nature long period RV variations ...

AST111, Lecture 1b

... emitted. For many bodies the total energy absorbed by the sun balances that emitted thermally. However, many planets also have internal heat sources. • There can be diurnal (daily), latitudinal and seasonal variations in temperature. Radiation transfer through the atmosphere can be complex (such as ...

slides

... Interactions with planetesimal disks will cause planets to migrate which in turn can lead to instabilities within a planetary system. This process probably played an important role in the early history of our own Solar System. e.g. Fernandez & Ip 1984; Hahn & ...

850616SemStudyGuide_AstSns

... A galaxy is a group of stars, gas and dust held together by gravity. There are 3 main types: spiral, elliptical, and irregular. Spiral galaxies can be normal or barred. They contain lots of gas and dust and relatively young stars. Elliptical galaxies are those that are shaped like an oval, a circle ...

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Planetary habitability

Planetary habitability is the measure of a planet's or a natural satellite's potential to develop and sustain life. Life may develop directly on a planet or satellite or be transferred to it from another body, a theoretical process known as panspermia. As the existence of life beyond Earth is unknown, planetary habitability is largely an extrapolation of conditions on Earth and the characteristics of the Sun and Solar System which appear favourable to life's flourishing—in particular those factors that have sustained complex, multicellular organisms and not just simpler, unicellular creatures. Research and theory in this regard is a component of planetary science and the emerging discipline of astrobiology.An absolute requirement for life is an energy source, and the notion of planetary habitability implies that many other geophysical, geochemical, and astrophysical criteria must be met before an astronomical body can support life. In its astrobiology roadmap, NASA has defined the principal habitability criteria as ""extended regions of liquid water, conditions favourable for the assembly of complex organic molecules, and energy sources to sustain metabolism.""In determining the habitability potential of a body, studies focus on its bulk composition, orbital properties, atmosphere, and potential chemical interactions. Stellar characteristics of importance include mass and luminosity, stable variability, and high metallicity. Rocky, terrestrial-type planets and moons with the potential for Earth-like chemistry are a primary focus of astrobiological research, although more speculative habitability theories occasionally examine alternative biochemistries and other types of astronomical bodies.The idea that planets beyond Earth might host life is an ancient one, though historically it was framed by philosophy as much as physical science. The late 20th century saw two breakthroughs in the field. The observation and robotic spacecraft exploration of other planets and moons within the Solar System has provided critical information on defining habitability criteria and allowed for substantial geophysical comparisons between the Earth and other bodies. The discovery of extrasolar planets, beginning in the early 1990s and accelerating thereafter, has provided further information for the study of possible extraterrestrial life. These findings confirm that the Sun is not unique among stars in hosting planets and expands the habitability research horizon beyond the Solar System.The chemistry of life may have begun shortly after the Big Bang, 13.8 billion years ago, during a habitable epoch when the Universe was only 10–17 million years old. According to the panspermia hypothesis, microscopic life—distributed by meteoroids, asteroids and other small Solar System bodies—may exist throughout the universe. Nonetheless, Earth is the only place in the universe known to harbor life. Estimates of habitable zones around other stars, along with the discovery of hundreds of extrasolar planets and new insights into the extreme habitats here on Earth, suggest that there may be many more habitable places in the universe than considered possible until very recently. On 4 November 2013, astronomers reported, based on Kepler space mission data, that there could be as many as 40 billion Earth-sized planets orbiting in the habitable zones of Sun-like stars and red dwarfs within the Milky Way. 11 billion of these estimated planets may be orbiting Sun-like stars. The nearest such planet may be 12 light-years away, according to the scientists.

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Planetary habitability