W. David Arnett

Last updated

W. David Arnett
William David Arnett, 2008, US astrophysicist, University of Arizona.jpg
Arnett in 2008
Born1940
NationalityAmerican
Alma mater Yale University
Known for nuclear astrophysics
supernovae
Awards Hans Bethe Prize (2009)
Henry Norris Russell Lectureship
Scientific career
Fields Astrophysics
Institutions University of Chicago
University of Arizona
Doctoral advisor Alastair G. W. Cameron

William David Arnett (born 1940) is a Regents Professor of Astrophysics at Steward Observatory, University of Arizona, [1] known for his research on supernova explosions, the formation of neutron stars or black holes by gravitational collapse, and the synthesis of elements in stars; he is author of the monograph Supernovae and Nucleosynthesis which deals with these topics. [2] Arnett pioneered the application of supercomputers to astrophysical problems, including neutrino radiation hydrodynamics, [3] [4] nuclear reaction networks, [5] instabilities and explosions, [6] [7] [8] supernova light curves, [9] [10] and turbulent convective flow in two [11] and three dimensions. [12]

Contents

Academic career

Arnett received his BS degree from the University of Kentucky in 1961 and his MS and PhD degrees in physics from Yale University in 1963 and 1965, advised by A. G. W. Cameron. After postdoctoral work with W. A. Fowler at the California Institute of Technology and Fred Hoyle at the Institute of Theoretical Astronomy (now Institute of Astronomy) of Cambridge University, he served briefly on the faculties of Rice University (working with Donald Clayton), University of Texas and University of Illinois before becoming the B. and E. Sunny Distinguished Service Professor at the University of Chicago and then Regents Professor [13] at the University of Arizona.

Honors and awards

Related Research Articles

<span class="mw-page-title-main">Supernova</span> Explosion of a star at its end of life

A supernova is a powerful and luminous explosion of a star. A supernova occurs during the last evolutionary stages of a massive star or when a white dwarf is triggered into runaway nuclear fusion. The original object, called the progenitor, either collapses to a neutron star or black hole, or is completely destroyed to form a diffuse nebula. The peak optical luminosity of a supernova can be comparable to that of an entire galaxy before fading over several weeks or months.

<span class="mw-page-title-main">SN 1987A</span> 1987 supernova event in the constellation Dorado

SN 1987A was a type II supernova in the Large Magellanic Cloud, a dwarf satellite galaxy of the Milky Way. It occurred approximately 51.4 kiloparsecs from Earth and was the closest observed supernova since Kepler's Supernova. 1987A's light reached Earth on February 23, 1987, and as the earliest supernova discovered that year, was labeled "1987A". Its brightness peaked in May of that year, with an apparent magnitude of about 3.

Nucleosynthesis is the process that creates new atomic nuclei from pre-existing nucleons and nuclei. According to current theories, the first nuclei were formed a few minutes after the Big Bang, through nuclear reactions in a process called Big Bang nucleosynthesis. After about 20 minutes, the universe had expanded and cooled to a point at which these high-energy collisions among nucleons ended, so only the fastest and simplest reactions occurred, leaving our universe containing hydrogen and helium. The rest is traces of other elements such as lithium and the hydrogen isotope deuterium. Nucleosynthesis in stars and their explosions later produced the variety of elements and isotopes that we have today, in a process called cosmic chemical evolution. The amounts of total mass in elements heavier than hydrogen and helium remains small, so that the universe still has approximately the same composition.

<span class="mw-page-title-main">Superluminous supernova</span> Supernova at least ten times more luminous than a standard supernova

A super-luminous supernova is a type of stellar explosion with a luminosity 10 or more times higher than that of standard supernovae. Like supernovae, SLSNe seem to be produced by several mechanisms, which is readily revealed by their light-curves and spectra. There are multiple models for what conditions may produce an SLSN, including core collapse in particularly massive stars, millisecond magnetars, interaction with circumstellar material, or pair-instability supernovae.

In astrophysics, silicon burning is a very brief sequence of nuclear fusion reactions that occur in massive stars with a minimum of about 8–11 solar masses. Silicon burning is the final stage of fusion for massive stars that have run out of the fuels that power them for their long lives in the main sequence on the Hertzsprung–Russell diagram. It follows the previous stages of hydrogen, helium, carbon, neon and oxygen burning processes.

<i>r</i>-process Nucleosynthesis pathway

In nuclear astrophysics, the rapid neutron-capture process, also known as the r-process, is a set of nuclear reactions that is responsible for the creation of approximately half of the atomic nuclei heavier than iron, the "heavy elements", with the other half produced by the p-process and s-process. The r-process usually synthesizes the most neutron-rich stable isotopes of each heavy element. The r-process can typically synthesize the heaviest four isotopes of every heavy element, and the two heaviest isotopes, which are referred to as r-only nuclei, can be created via the r-process only. Abundance peaks for the r-process occur near mass numbers A = 82, A = 130 and A = 196.

The slow neutron-capture process, or s-process, is a series of reactions in nuclear astrophysics that occur in stars, particularly asymptotic giant branch stars. The s-process is responsible for the creation (nucleosynthesis) of approximately half the atomic nuclei heavier than iron.

The term p-process (p for proton) is used in two ways in the scientific literature concerning the astrophysical origin of the elements (nucleosynthesis). Originally it referred to a proton capture process which was proposed to be the source of certain, naturally occurring, neutron-deficient isotopes of the elements from selenium to mercury. These nuclides are called p-nuclei and their origin is still not completely understood. Although it was shown that the originally suggested process cannot produce the p-nuclei, later on the term p-process was sometimes used to generally refer to any nucleosynthesis process supposed to be responsible for the p-nuclei.

Supernova nucleosynthesis is the nucleosynthesis of chemical elements in supernova explosions.

<span class="mw-page-title-main">Type Ia supernova</span> Type of supernova in binary systems

A Type Ia supernova is a type of supernova that occurs in binary systems in which one of the stars is a white dwarf. The other star can be anything from a giant star to an even smaller white dwarf.

<span class="mw-page-title-main">Type II supernova</span> Explosion of a star 8 to 45 times the mass of the Sun

A Type II supernova or SNII results from the rapid collapse and violent explosion of a massive star. A star must have at least eight times, but no more than 40 to 50 times, the mass of the Sun (M) to undergo this type of explosion. Type II supernovae are distinguished from other types of supernovae by the presence of hydrogen in their spectra. They are usually observed in the spiral arms of galaxies and in H II regions, but not in elliptical galaxies; those are generally composed of older, low-mass stars, with few of the young, very massive stars necessary to cause a supernova.

<span class="mw-page-title-main">Pair-instability supernova</span> Type of high-energy supernova in very large stars

A pair-instability supernova is a type of supernova predicted to occur when pair production, the production of free electrons and positrons in the collision between atomic nuclei and energetic gamma rays, temporarily reduces the internal radiation pressure supporting a supermassive star's core against gravitational collapse. This pressure drop leads to a partial collapse, which in turn causes greatly accelerated burning in a runaway thermonuclear explosion, resulting in the star being blown completely apart without leaving a stellar remnant behind.

p-nuclei (p stands for proton-rich) are certain proton-rich, naturally occurring isotopes of some elements between selenium and mercury inclusive which cannot be produced in either the s- or the r-process.

<span class="mw-page-title-main">Donald D. Clayton</span> American astrophysicist

Donald Delbert Clayton is an American astrophysicist whose most visible achievement was the prediction from nucleosynthesis theory that supernovae are intensely radioactive. That earned Clayton the NASA Exceptional Scientific Achievement Medal (1992) for “theoretical astrophysics related to the formation of (chemical) elements in the explosions of stars and to the observable products of these explosions”. Supernovae thereafter became the most important stellar events in astronomy owing to their profoundly radioactive nature. Not only did Clayton discover radioactive nucleosynthesis during explosive silicon burning in stars but he also predicted a new type of astronomy based on it, namely the associated gamma-ray line radiation emitted by matter ejected from supernovae. That paper was selected as one of the fifty most influential papers in astronomy during the twentieth century for the Centennial Volume of the American Astronomical Society. He gathered support from influential astronomers and physicists for a new NASA budget item for a gamma-ray-observatory satellite, achieving successful funding for Compton Gamma Ray Observatory. With his focus on radioactive supernova gas Clayton discovered a new chemical pathway causing carbon dust to condense there by a process that is activated by the radioactivity.

James Michael Lattimer is a nuclear astrophysicist who works on the dense nuclear matter equation of state and neutron stars.

<span class="mw-page-title-main">Hypernova</span> Supernova that ejects a large mass at unusually high velocity

A hypernova is a very energetic supernova which is believed to result from an extreme core-collapse scenario. In this case, a massive star collapses to form a rotating black hole emitting twin astrophysical jets and surrounded by an accretion disk. It is a type of stellar explosion that ejects material with an unusually high kinetic energy, an order of magnitude higher than most supernovae, with a luminosity at least 10 times greater. They usually appear similar to a type Ic supernova, but with unusually broad spectral lines indicating an extremely high expansion velocity. Hypernovae are one of the mechanisms for producing long gamma ray bursts (GRBs), which range from 2 seconds to over a minute in duration. They have also been referred to as superluminous supernovae, though that classification also includes other types of extremely luminous stellar explosions that have different origins.

Supernova neutrinos are weakly interactive elementary particles produced during a core-collapse supernova explosion. A massive star collapses at the end of its life, emitting on the order of 1058 neutrinos and antineutrinos in all lepton flavors. The luminosity of different neutrino and antineutrino species are roughly the same. They carry away about 99% of the gravitational energy of the dying star as a burst lasting tens of seconds. The typical supernova neutrino energies are 10 to 20 MeV. Supernovae are considered the strongest and most frequent source of cosmic neutrinos in the MeV energy range.

James Wellington Truran Jr. was an American physicist, known for his research in nuclear astrophysics.

James "Jim" Ricker Wilson was an American theoretical physicist, known for his pioneering research in numerical relativity and numerical relativistic hydrodynamics.

George Michael Fuller is an American theoretical physicist, known for his research on nuclear astrophysics involving weak interactions, neutrino flavor-mixing, and quark matter, as well as the hypothetical nuclear matter.

References

  1. "W. David Arnett". As.arizona.edu. Retrieved December 9, 2013.
  2. Arnett, David (1996). Supernovae and Nucleosynthesis: An Investigation of the History of Matter, from the Big Bang to the Present. Princeton University Press. ISBN   978-0-691-01147-9.
  3. W. D. Arnett (1966). "Gravitational Collapse and Weak Interactions". Canadian Journal of Physics. 44 (11): 2553–2594. Bibcode:1966CaJPh..44.2553A. doi:10.1139/p66-210. hdl: 2060/19670009027 .
  4. W. D. Arnett (1977). "Neutrino trapping during gravitational collapse of stars". Astrophysical Journal. 218: 815. Bibcode:1977ApJ...218..815A. doi: 10.1086/155738 .
  5. W. D. Arnett; J. W. Truran (1969). "Carbon-Burning Nucleosynthesis at Constant Temperature". Astrophysical Journal. 157: 339. Bibcode:1969ApJ...157..339A. doi:10.1086/150072.
  6. W. D. Arnett (1969). "Pulsars and Neutron Star Formation". Nature. 222 (5191): 359–361. Bibcode:1969Natur.222..359A. doi:10.1038/222359b0. S2CID   4212202.
  7. W. D. Arnett (1969). "A possible model of supernovae: Detonation of12C". Astrophysics and Space Science. 5 (2): 180–212. Bibcode:1969Ap&SS...5..180A. doi:10.1007/BF00650291. S2CID   120310982.
  8. B. Fryxell; W. D. Arnett; E. Mueller (1991). "Instabilities and clumping in SN 1987A. I - Early evolution in two dimensions". Astrophysical Journal. 367: 619. Bibcode:1991ApJ...367..619F. doi: 10.1086/169657 .
  9. S. W. Falk; W. D. Arnett (1977). "Radiation Dynamics, Envelope Ejection, and Supernova Light Curves". Astrophysical Journal. 33: 515. Bibcode:1977ApJS...33..515F. doi:10.1086/190440.
  10. W. D. Arnett (1982). "Type I supernovae. I - Analytic solutions for the early part of the light curve". Astrophysical Journal. 253: 785. Bibcode:1982ApJ...253..785A. doi:10.1086/159681.
  11. G. Bazan; W. D. Arnett (1994). "Convection, Nucleosynthesis, and Core Collapse". Astrophysical Journal. 433: 41. Bibcode:1994ApJ...433L..41B. doi: 10.1086/187543 .
  12. C. Meakin; W. D. Arnett (2007). "Turbulent Convection in Stellar Interiors. I. Hydrodynamic Simulation". Astrophysical Journal. 667 (1): 448–475. arXiv: astro-ph/0611315 . Bibcode:2007ApJ...667..448M. doi:10.1086/520318. S2CID   5694141.
  13. "Regents Professors | The University of Arizona, Tucson, Arizona". Arizona.edu. Retrieved December 9, 2013.
  14. "Henry Norris Russell Lectureship | American Astronomical Society". Aas.org. Archived from the original on January 19, 2016. Retrieved December 9, 2013.
  15. "Marcel Grossmann Awards". Icra.it. Retrieved December 9, 2013.
  16. "Hans A. Bethe Prize". Aps.org. April 16, 2013. Retrieved December 9, 2013.
  17. "APS Fellow Archive". APS. Retrieved September 23, 2020.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.