W Where Did Half the Starlight in the Universe Go? Mark Devlin

... Kelvin. The COBE satellite made the first measurements of the resulting Far Infrared Background (FIRB), but since that time, we have been unable to resolve the background into individual galaxies. The Balloon-borne Large Aperture Submillimeter Telescope (BLAST) was designed to do this job. Its three ...

AST301.Ch21.StellarExpl - University of Texas Astronomy

... and the s-process patterns. This is amazing agreement considering that we are not even sure about the details of stellar explosions. 2. Technetium—this element is predicted to be produced in the sprocess, but it is radioactive, and decays in 200,000 years. Yet it is observed in the atmospheres of so ...

Chapter 21 power point - Laconia School District

... the upper left to the lower right and includes more than 90% of all stars. ...

"Magnetic Field Structure in Relativistic Jets", H. Jermak

... - First operational in 2006 when it detected its first GRB (060418). ...

Astronomy I Ex.2

... What is the (approximate) age of the universe in Gyr? 3. Convert the following distances in cm to distances in AU: a) Approximate distance from the earth to the sun: 1.44 × 1013 cm b) Approximate distance from the earth to the next nearest star - Alpha Centauri: 3.97 × 1018 cm c) Approximate distanc ...

The Sun and Beyond - Valhalla High School

The Stars

...  There are more stars in the sky than anyone can easily count, but they are not scattered evenly, and they are not all the same in brightness or color. By the end of the 5th grade, students should know that  The patterns of stars in the sky stay the same, although they appear to move across the sk ...

Astronomy - Wappingers Central School District

Ch. 28 Test Topics

... -186,000 miles per second -671 million miles per hour -A light year is distance light can travel in a year. -9.5 x 1012 km -about 6 trillion miles -Know what an Astronomical Unit (AU) is. -Distance from Earth to Sun -1.5 x 108 km = 1 AU -Know the closest galaxy similar in size (Andromeda; 2.5 millio ...

The Evolution of Massive Stars

... • Pulse of neutrinos as core collapses • “Pollution” of the interstellar medium as explosion blows off the outer stellar core • Birth of the “neutron star” ...

Chapter 30

... bright in the center and do not have spiral arms. ...

Gamma Rays - Ohio University Physics and Astronomy

... => Need long integration times to measure a significant signal Sensitivity limit for detection of a source at a confidence level of n s (i.e., an excess of n times the standard deviation of the background g-ray flux dFB/dE): ...

Cosmic Rays - Astroteilchenschule

... The superimposed (linearly spaced) black contour lines show the X-ray surface brightness as seen by ASCA in the 1–3 keV range. ...

PHYS 175 Fall 2014 Final Recitation Ch. 16 The Sun

... Photons released in the core (where fusion takes place) collide almost instantaneously with other core constituents. This energy gradually flows outward, until the density of the sun decreases sufficiently to allow for radiative diffusion of the energy. Again, the photons still undergo many collisio ...

Name ______KEY Date Core ______ Study Guide Galaxies and the

... When did the Big Bang happen and what has happened since? The big bang theory is theorized to have happened 14 billion years ago when the universe suddenly began to expand from one merged mass of matter or substance. At that time, all matter was dense and hot and the universe developed in less than ...

Galaxies and the Universe

Galaxies and the Universe

... • unit of distance equal to the average spacing between the Earth and the Sun • equal to about 150 million kilometers (93 ...

Microsoft Word 97

... 1. When did the Milky Way begin? _____________________________________________________ 2. Where does its name come from? ___________________________________________________ 3. What do we see when we look in the sky? _____________________________________________ 4. What does our galaxy look like from ...

ASTR220 Collisions in Space

Components of Universe

... Surface of Sun – Gas bubbles ...

a repeating fast radio burst

... reside in neighboring galaxies that are only hundreds of millions of lightyears away. The observed brightnesses of fast radio bursts, coupled with the substantial distances involved, imply that FRBs are energetic events, releasing in milliseconds the amount of energy the Sun produces in days. This h ...

Chapter 28 Vocabulary

... Astronomical Unit – the average distance between Earth and the sun, about 150 million kilometers. ...

Lectures 14 & 15 powerpoint (neutron stars & black holes)

... Some of these GRBs repeat – known as “soft gamma-ray repeaters,” “soft” = low energy gamma rays. We suspect that these originate from neutron stars with really strong magnetic fields (“magnetars”). When shifts in the magnetic field breaks through the crust of a magnetar, bursts of gamma rays are emi ...

Study Guide

... What 3 things are used to classify stars? a. ______________________________ ...

Lives and Deaths of Stars (middle school)

... A star will live until all hydrogen is exhausted in its core Our Sun will live 5 billion years more ...

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Gamma-ray burst

Gamma-ray bursts (GRBs) are flashes of gamma rays associated with extremely energetic explosions that have been observed in distant galaxies. They are the brightest electromagnetic events known to occur in the universe. Bursts can last from ten milliseconds to several hours. The initial burst is usually followed by a longer-lived ""afterglow"" emitted at longer wavelengths (X-ray, ultraviolet, optical, infrared, microwave and radio).Most observed GRBs are believed to consist of a narrow beam of intense radiation released during a supernova or hypernova as a rapidly rotating, high-mass star collapses to form a neutron star, quark star, or black hole. A subclass of GRBs (the ""short"" bursts) appear to originate from a different process – this may be due to the merger of binary neutron stars. The cause of the precursor burst observed in some of these short events may be due to the development of a resonance between the crust and core of such stars as a result of the massive tidal forces experienced in the seconds leading up to their collision, causing the entire crust of the star to shatter.The sources of most GRBs are billions of light years away from Earth, implying that the explosions are both extremely energetic (a typical burst releases as much energy in a few seconds as the Sun will in its entire 10-billion-year lifetime) and extremely rare (a few per galaxy per million years). All observed GRBs have originated from outside the Milky Way galaxy, although a related class of phenomena, soft gamma repeater flares, are associated with magnetars within the Milky Way. It has been hypothesized that a gamma-ray burst in the Milky Way, pointing directly towards the Earth, could cause a mass extinction event.GRBs were first detected in 1967 by the Vela satellites, a series of satellites designed to detect covert nuclear weapons tests. Hundreds of theoretical models were proposed to explain these bursts in the years following their discovery, such as collisions between comets and neutron stars. Little information was available to verify these models until the 1997 detection of the first X-ray and optical afterglows and direct measurement of their redshifts using optical spectroscopy, and thus their distances and energy outputs. These discoveries, and subsequent studies of the galaxies and supernovae associated with the bursts, clarified the distance and luminosity of GRBs. These facts definitively placed them in distant galaxies and also connected long GRBs with the explosion of massive stars, the only possible source for the energy outputs observed.

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Gamma-ray burst