Explanation of anomalous shock temperatures in shock-loaded Mo samples measured using neutron resonance spectroscopy

Neutron resonance spectrometry (NRS) has been used to measure the temperature inside Mo samples during shock loading. The temperatures obtained were significantly higher than predicted assuming ideal hydrodynamic loading, a discrepancy which we now explain. The effects of plastic flow and nonideal p...

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Veröffentlicht in:	Physical review. B, Condensed matter and materials physics Condensed matter and materials physics, 2008-03, Vol.77 (9), Article 092102
Hauptverfasser:	Swift, Damian C., Seifter, Achim, Holtkamp, David B., Yuan, Vincent W., Bowman, David, Clark, David A.
Format:	Artikel
Sprache:	eng
Schlagworte:	CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY CORRECTIONS EQUATIONS OF STATE HYDRODYNAMICS MOLYBDENUM NEUTRON SPECTROSCOPY NEUTRONS RESONANCE SIMULATION TEMPERATURE RANGE 0065-0273 K THERMAL SHOCK VELOCITY
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container_title	Physical review. B, Condensed matter and materials physics
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creator	Swift, Damian C. Seifter, Achim Holtkamp, David B. Yuan, Vincent W. Bowman, David Clark, David A.
description	Neutron resonance spectrometry (NRS) has been used to measure the temperature inside Mo samples during shock loading. The temperatures obtained were significantly higher than predicted assuming ideal hydrodynamic loading, a discrepancy which we now explain. The effects of plastic flow and nonideal projectile behavior were assessed. Plastic flow was calculated self-consistently with the shock jump conditions: this is necessary for a rigorous estimate of the locus of shock states accessible. Plastic flow was estimated to contribute a temperature rise of 53 K compared with hydrodynamic flow. Simulations were performed of the operation of the explosively driven projectile system used to induce the shock in the Mo sample. The simulations, and related experiments, indicated that the projectile was significantly curved on impact, and still accelerating. The resulting spatial variations in load, including radial components of velocity, should increase the apparent temperature that would be deduced from the width of the neutron resonance by 160 K. These corrections are sufficient to reconcile the apparent temperatures deduced using NRS with the accepted properties of Mo, in particular, its equation of state.
doi_str_mv	10.1103/PhysRevB.77.092102
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The temperatures obtained were significantly higher than predicted assuming ideal hydrodynamic loading, a discrepancy which we now explain. The effects of plastic flow and nonideal projectile behavior were assessed. Plastic flow was calculated self-consistently with the shock jump conditions: this is necessary for a rigorous estimate of the locus of shock states accessible. Plastic flow was estimated to contribute a temperature rise of 53 K compared with hydrodynamic flow. Simulations were performed of the operation of the explosively driven projectile system used to induce the shock in the Mo sample. The simulations, and related experiments, indicated that the projectile was significantly curved on impact, and still accelerating. The resulting spatial variations in load, including radial components of velocity, should increase the apparent temperature that would be deduced from the width of the neutron resonance by 160 K. 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The resulting spatial variations in load, including radial components of velocity, should increase the apparent temperature that would be deduced from the width of the neutron resonance by 160 K. 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B, Condensed matter and materials physics</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Swift, Damian C.</au><au>Seifter, Achim</au><au>Holtkamp, David B.</au><au>Yuan, Vincent W.</au><au>Bowman, David</au><au>Clark, David A.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Explanation of anomalous shock temperatures in shock-loaded Mo samples measured using neutron resonance spectroscopy</atitle><jtitle>Physical review. B, Condensed matter and materials physics</jtitle><date>2008-03-01</date><risdate>2008</risdate><volume>77</volume><issue>9</issue><artnum>092102</artnum><issn>1098-0121</issn><eissn>1550-235X</eissn><abstract>Neutron resonance spectrometry (NRS) has been used to measure the temperature inside Mo samples during shock loading. The temperatures obtained were significantly higher than predicted assuming ideal hydrodynamic loading, a discrepancy which we now explain. The effects of plastic flow and nonideal projectile behavior were assessed. Plastic flow was calculated self-consistently with the shock jump conditions: this is necessary for a rigorous estimate of the locus of shock states accessible. Plastic flow was estimated to contribute a temperature rise of 53 K compared with hydrodynamic flow. Simulations were performed of the operation of the explosively driven projectile system used to induce the shock in the Mo sample. The simulations, and related experiments, indicated that the projectile was significantly curved on impact, and still accelerating. The resulting spatial variations in load, including radial components of velocity, should increase the apparent temperature that would be deduced from the width of the neutron resonance by 160 K. These corrections are sufficient to reconcile the apparent temperatures deduced using NRS with the accepted properties of Mo, in particular, its equation of state.</abstract><cop>United States</cop><doi>10.1103/PhysRevB.77.092102</doi></addata></record>
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subjects	CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY CORRECTIONS EQUATIONS OF STATE HYDRODYNAMICS MOLYBDENUM NEUTRON SPECTROSCOPY NEUTRONS RESONANCE SIMULATION TEMPERATURE RANGE 0065-0273 K THERMAL SHOCK VELOCITY
title	Explanation of anomalous shock temperatures in shock-loaded Mo samples measured using neutron resonance spectroscopy
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