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Trapping of hydrogen and helium at dislocations in tungsten: an ab initio study

The interaction of H or He atoms with a core of edge and screw dislocations (SDs), with Burgers vector a0/2〈111〉, is studied by means of ab initio calculations. The results show that the edge dislocations are stronger traps for H and He compared to the SDs, while the H/He affinity to both types of d...

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Published in:	Nuclear fusion 2017-12, Vol.57 (12), p.126040
Main Authors:	Bakaev, A., Grigorev, P., Terentyev, D., Bakaeva, A., Zhurkin, E.E., Mastrikov, Yu. A.
Format:	Article
Language:	English
Subjects:	dislocations helium hydrogen molecular statics plasma tungsten
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container_title	Nuclear fusion
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creator	Bakaev, A. Grigorev, P. Terentyev, D. Bakaeva, A. Zhurkin, E.E. Mastrikov, Yu. A.
description	The interaction of H or He atoms with a core of edge and screw dislocations (SDs), with Burgers vector a0/2〈111〉, is studied by means of ab initio calculations. The results show that the edge dislocations are stronger traps for H and He compared to the SDs, while the H/He affinity to both types of dislocation is significantly weaker than to a single vacancy. The lowest energy atomic configurations are rationalized on the basis of the charge density distribution and elasticity theory considerations. The results obtained contribute to the rationalization of the thermal desorption spectroscopy analysis by attributing certain peaks of the release of plasma components to the detrapping from dislocations. Complementary molecular statics (MS) calculations are performed to validate the accuracy of the recently developed W-H-He embedded atom method (EAM) and bond-order potentials. It is revealed that the EAM potential can reproduce correctly the magnitude of the interaction of H with both dislocations as compared to the ab initio results. All the potentials underestimate significantly the He-dislocation interaction and cannot describe correctly the lowest energy positions for H and He around the dislocation core. The reason for the discrepancy between ab initio and the MS results is rationalized by the analysis of the fully relaxed atomic configurations.
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Complementary molecular statics (MS) calculations are performed to validate the accuracy of the recently developed W-H-He embedded atom method (EAM) and bond-order potentials. It is revealed that the EAM potential can reproduce correctly the magnitude of the interaction of H with both dislocations as compared to the ab initio results. All the potentials underestimate significantly the He-dislocation interaction and cannot describe correctly the lowest energy positions for H and He around the dislocation core. 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A.</creatorcontrib><title>Trapping of hydrogen and helium at dislocations in tungsten: an ab initio study</title><title>Nuclear fusion</title><addtitle>NF</addtitle><addtitle>Nucl. Fusion</addtitle><description>The interaction of H or He atoms with a core of edge and screw dislocations (SDs), with Burgers vector a0/2〈111〉, is studied by means of ab initio calculations. The results show that the edge dislocations are stronger traps for H and He compared to the SDs, while the H/He affinity to both types of dislocation is significantly weaker than to a single vacancy. The lowest energy atomic configurations are rationalized on the basis of the charge density distribution and elasticity theory considerations. The results obtained contribute to the rationalization of the thermal desorption spectroscopy analysis by attributing certain peaks of the release of plasma components to the detrapping from dislocations. Complementary molecular statics (MS) calculations are performed to validate the accuracy of the recently developed W-H-He embedded atom method (EAM) and bond-order potentials. It is revealed that the EAM potential can reproduce correctly the magnitude of the interaction of H with both dislocations as compared to the ab initio results. All the potentials underestimate significantly the He-dislocation interaction and cannot describe correctly the lowest energy positions for H and He around the dislocation core. The reason for the discrepancy between ab initio and the MS results is rationalized by the analysis of the fully relaxed atomic configurations.</description><subject>dislocations</subject><subject>helium</subject><subject>hydrogen</subject><subject>molecular statics</subject><subject>plasma</subject><subject>tungsten</subject><issn>0029-5515</issn><issn>1741-4326</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><recordid>eNp9UD1rwzAUFKWFpmn3jtq61M2TJdlWtxL6BYEs6SxkS0oUEslI9uB_X4WUTqXw4MG9u8fdIXRP4IlA0yxIzUjBaFktlKpFxS_Q7Be6RDOAUhScE36NblLaAxBGKJ2h9Saqvnd-i4PFu0nHsDUeK6_xzhzceMRqwNqlQ-jU4IJP2Hk8jH6bBuOfMw-rNkMu33AaRj3doiurDsnc_ew5-np73Sw_itX6_XP5sio6SsqhIFaphjddJbQAU4vsBVpWGQtKgKhoq6nlraJtCawVrNa1IU0NQMu209QYOkdw_tvFkFI0VvbRHVWcJAF5KkSe0stTenkuJEsezxIXerkPY_TZ4H_0hz_o3kpeS1LmqYCB7LWl32dmbnk</recordid><startdate>20171201</startdate><enddate>20171201</enddate><creator>Bakaev, A.</creator><creator>Grigorev, P.</creator><creator>Terentyev, D.</creator><creator>Bakaeva, A.</creator><creator>Zhurkin, E.E.</creator><creator>Mastrikov, Yu. 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A.</creatorcontrib><collection>CrossRef</collection><jtitle>Nuclear fusion</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Bakaev, A.</au><au>Grigorev, P.</au><au>Terentyev, D.</au><au>Bakaeva, A.</au><au>Zhurkin, E.E.</au><au>Mastrikov, Yu. A.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Trapping of hydrogen and helium at dislocations in tungsten: an ab initio study</atitle><jtitle>Nuclear fusion</jtitle><stitle>NF</stitle><addtitle>Nucl. Fusion</addtitle><date>2017-12-01</date><risdate>2017</risdate><volume>57</volume><issue>12</issue><spage>126040</spage><pages>126040-</pages><issn>0029-5515</issn><eissn>1741-4326</eissn><coden>NUFUAU</coden><abstract>The interaction of H or He atoms with a core of edge and screw dislocations (SDs), with Burgers vector a0/2〈111〉, is studied by means of ab initio calculations. The results show that the edge dislocations are stronger traps for H and He compared to the SDs, while the H/He affinity to both types of dislocation is significantly weaker than to a single vacancy. The lowest energy atomic configurations are rationalized on the basis of the charge density distribution and elasticity theory considerations. The results obtained contribute to the rationalization of the thermal desorption spectroscopy analysis by attributing certain peaks of the release of plasma components to the detrapping from dislocations. Complementary molecular statics (MS) calculations are performed to validate the accuracy of the recently developed W-H-He embedded atom method (EAM) and bond-order potentials. It is revealed that the EAM potential can reproduce correctly the magnitude of the interaction of H with both dislocations as compared to the ab initio results. All the potentials underestimate significantly the He-dislocation interaction and cannot describe correctly the lowest energy positions for H and He around the dislocation core. The reason for the discrepancy between ab initio and the MS results is rationalized by the analysis of the fully relaxed atomic configurations.</abstract><pub>IOP Publishing</pub><doi>10.1088/1741-4326/aa7965</doi><tpages>13</tpages></addata></record>
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subjects	dislocations helium hydrogen molecular statics plasma tungsten
title	Trapping of hydrogen and helium at dislocations in tungsten: an ab initio study
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