FROM STARS TO CARS December 2012

... of stars. Our own sun is one of these, a youngster at only 4.5 billion years old. That same cloud of interstellar matter that formed the sun also formed the planets around it. The gravitational pull of the sun is stronger for heavier elements and their condensation point higher. Once these elements ...

Astronomy Learning Objectives and Study Questions for Chapter 13

... the major "legs" of its evolutionary path on an H-R diagram (see Figures 12-1 and 123). 2. Predict what type of objects each of three isolated stars will become if, at the ends of their lives, their cores have masses of: 2.0, 1.2 and 5.5 solar masses, respectively. 3. Explain why the Sun will or wil ...

Notes: Stellar Nucleosynthesis

... Fusion of Heavier Elements • Iron is a “star killer” • fusion of iron takes energy (endothermic) instead of giving off energy (exothermic) • therefore, stars begin to “die” once iron is created. ...

The H-R Diagram

... as many more particles created by the fact E=mc2 and so new massive particles can be created out of available energy. Pions, kaons, lambdas, muons (most of what arrives at sea level are muons), and many more particles you don’t hear about much because they decay rapidly in ordinary circumstances… • ...

document

... THE LIFE OF OUR UNIVERSE IS ABOUT 14 BILLION YEARS. LIGHT SIGNALS HAVE NOT HAD TIME TO TRAVEL MORE THAN 14 BILLION LIGHT YEARS. SO, WE CAN’T OBSERVE ANYTHING OUTSIDE OF THIS SPHERE. “Our currently observable universe is but one small part of a greater whole. But if the laws of physics can enforce t ...

Our Place in the Universe: Sizing up the Heavens

... •Color (spectrum) and apparent variations through time  composition, temperature, direction of motion and velocity relative to observer. •Apparent Size and shape and variations through time  stars, galaxies, nebula (clouds of dust and gas), comets, ...

nuclear astrophysics applications for accelerators

... The development of spectroscopy has allowed the chemical abundances of stars (and other objects) to be evaluated. Several important features are observed. Firstly, the vast majority of material (‘matter’ – we’re not considering dark matter or dark energy here) is composed of hydrogen (typically ~74 ...

the atomic model - Biology2014-7

... of nature has been unified The electromagnetic, strong and weak forces form GUT Theory ...

THE HISTORY OF THE UNIVERSE IN ONE EASY LESSON

... THE LIFE OF OUR UNIVERSE IS ABOUT 14 BILLION YEARS. LIGHT SIGNALS HAVE NOT HAD TIME TO TRAVEL MORE THAN 14 BILLION LIGHT YEARS. SO, WE CAN’T OBSERVE ANYTHING OUTSIDE OF THIS SPHERE. “Our currently observable universe is but one small part of a greater whole. But if the laws of physics can enforce t ...

Genesis of the Heaviest Elements in the Milky Way Galaxy

... for nearly all of the ordinary matter; the rest of the Periodic Table provides only trace elements. Among the remaining elements, the distribution features rapidly declining abundances with increasing atomic number Z, an odd/even pattern with even-Z elements being more abundant than their immediate ...

The Universe - The Ohio State University

... Astronomers think that such jets are important vehicles for transporting energy from the black hole to the much larger dimensions of a galaxy, and affecting the rate at which stars form there. Blackholes are end products of stellar evolution of giant stars. Numerous smaller black holes in binary sta ...

Big Bang and Beyond

... • Hoyle calculated the temperature inside a large star to be about 100 million degrees • and worked out how much kinetic energy this would give to the particles rushing around in the star's atmosphere. • Knowing the masses of both beryllium-8 and Helium, his hypothesis predicted that there must be a ...

L1_Intro - Department of Earth and Planetary Sciences

... 3 - 300 million species; ~1.5 million identified VERY significant geological agent (Ex: atmosphere, weathering) ...

Slide 1

... • Finally, as a white dwarf, it appears below the main sequence ...

No Slide Title

... Or “grey dust” or ?? ...

When radiation ruled

... Purdue? Could you see stars at night? ...

Lecture 1: Welcome to Astronomy 106

... One of their uses is to study the expansion of the Universe (see ASTR 106) ...

Evolution and nucleosynthesis of extremely metal

... binary system mass-transfer via wind accretion or Roche-lobe overflow from a star such as that modelled here (which would now be a white dwarf). Subsequent dilution of the accreted material in the envelope of HE 1327-2326 via convection or thermohaline mixing would be expected (Stancliffe & Glebbeek ...

Science Quiz

... The Sun-How do prominences and solar flares (CME’s) affect Earth? What protects Earth from CME’s? ...

Supernovae — Oct 18 10/18/2010

... What is the only element at the start? How many neutrons does it have? At what time did some gold form? Gold has 79 protons. Is this gold stable? At the end of the calculation, how many protons does the nucleus with the most protons have? What is the time at the end of the calculation? Are the end p ...

The Hidden Lives of Galaxies NSTA 2001

... • Under collapse, protons and electrons combine to form neutrons. • 10 Km across Black Hole (If mass of core > 5 x Solar) • Not even compacted neutrons can support weight of very massive stars. ...

I. Abundances – The Composition of the Universe

... 1929 Russell: calibrated solar spectral data to obtain table of abundances 1937 Goldschmidt: First analysis of “primordial” abundances: meteorites, sun 1956 Suess and Urey “Abundances of the Elements”, Rev. Mod. Phys. 28 (1956) 53 ...

Stellar Death High Mass Stars

...  Energy debt results  Core contracts - temperature increases Uncontrollable gravitational collapse vNuclei converted back into He He  protons and neutrons proton + electron  neutron + neutrino vCore Implodes  Envelope Explodes Supernova ...

Yes - Wichita State University

... •Measure the oxygen gradient in the ISM of the Milky Way disk •Employ planetary nebulae as abundance probes •Perform detailed statistical treatment of data ...

Review Quiz No. 17

... The radius in the interior of a star where fusion processes can no longer take place. The point in time of a star’s life when nuclear fusion of hydrogen into helium ceases. The point in time of a star’s life when nuclear fusion processes cease alltogether. The point in a rotating star cluster beyond ...

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Nucleosynthesis

Nucleosynthesis is the process that creates new atomic nuclei from pre-existing nucleons, primarily protons and neutrons. The first nuclei were formed about three minutes after the Big Bang, through the process called Big Bang nucleosynthesis. It was then that hydrogen and helium formed to become the content of the first stars, and this primeval process is responsible for the present hydrogen/helium ratio of the cosmos.With the formation of stars, heavier nuclei were created from hydrogen and helium by stellar nucleosynthesis, a process that continues today. Some of these elements, particularly those lighter than iron, continue to be delivered to the interstellar medium when low mass stars eject their outer envelope before they collapse to form white dwarfs. The remains of their ejected mass form the planetary nebulae observable throughout our galaxy.Supernova nucleosynthesis within exploding stars by fusing carbon and oxygen is responsible for the abundances of elements between magnesium (atomic number 12) and nickel (atomic number 28). Supernova nucleosynthesis is also thought to be responsible for the creation of rarer elements heavier than iron and nickel, in the last few seconds of a type II supernova event. The synthesis of these heavier elements absorbs energy (endothermic) as they are created, from the energy produced during the supernova explosion. Some of those elements are created from the absorption of multiple neutrons (the R process) in the period of a few seconds during the explosion. The elements formed in supernovas include the heaviest elements known, such as the long-lived elements uranium and thorium.Cosmic ray spallation, caused when cosmic rays impact the interstellar medium and fragment larger atomic species, is a significant source of the lighter nuclei, particularly 3He, 9Be and 10,11B, that are not created by stellar nucleosynthesis.In addition to the fusion processes responsible for the growing abundances of elements in the universe, a few minor natural processes continue to produce very small numbers of new nuclides on Earth. These nuclides contribute little to their abundances, but may account for the presence of specific new nuclei. These nuclides are produced via radiogenesis (decay) of long-lived, heavy, primordial radionuclides such as uranium and thorium. Cosmic ray bombardment of elements on Earth also contribute to the presence of rare, short-lived atomic species called cosmogenic nuclides.

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Nucleosynthesis