Computed molecular depth profile for $C_{60}$ bombardment of a molecular solid

Paruch, Robert J.; Garrison, Barbara J.; Postawa, Zbigniew

doi:10.1021/ac403035a

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Computed molecular depth profile for bombardment of a molecular solid

2013

journal article

article

10.1021/ac403035a

Journal

Analytical Chemistry

Author

Paruch Robert J.

Garrison Barbara J.

Postawa Zbigniew

Volume

85

Number

23

Pages

11628-11633

ISSN

0003-2700

eISSN

1520-6882

Language

English

Journal language

English

Abstract in English

Molecular dynamics (MD) simulations have been performed for 10 keV bombardment of an octane molecular solid at normal incidence. The results are analyzed using the steady-state statistical sputtering model (SS-SSM) to understand the nature of molecular motions and to predict a depth profile of a -layer. The octane system has sputtering yield of 150 of which 85% is in intact molecules and 15% is fragmented species. The main displacement mechanism is along the crater edge. Displacements between layers beneath the impact point are difficult because the nonspherically shaped octane molecule needs a relatively large volume to move into and the molecule needs to be aligned properly for the displacement. Since interlayer mixing is difficult, the predicted depth profile is dominated by the rms roughness and the large information depth because of the large sputtering yield.

Scopus© citations

10

dc.abstract.en	Molecular dynamics (MD) simulations have been performed for 10 keV $C_{60}$ bombardment of an octane molecular solid at normal incidence. The results are analyzed using the steady-state statistical sputtering model (SS-SSM) to understand the nature of molecular motions and to predict a depth profile of a $\delta$-layer. The octane system has sputtering yield of $\sim$ 150 $nm^{3}$ of which 85% is in intact molecules and 15% is fragmented species. The main displacement mechanism is along the crater edge. Displacements between layers beneath the impact point are difficult because the nonspherically shaped octane molecule needs a relatively large volume to move into and the molecule needs to be aligned properly for the displacement. Since interlayer mixing is difficult, the predicted depth profile is dominated by the rms roughness and the large information depth because of the large sputtering yield.	pl
dc.affiliation	Wydział Fizyki, Astronomii i Informatyki Stosowanej : Instytut Fizyki im. Mariana Smoluchowskiego	pl
dc.contributor.author	Paruch, Robert J.	pl
dc.contributor.author	Garrison, Barbara J.	pl
dc.contributor.author	Postawa, Zbigniew - 100132	pl
dc.date.accessioned	2015-07-02T08:03:32Z
dc.date.available	2015-07-02T08:03:32Z
dc.date.issued	2013	pl
dc.description.admin	[AA] Paruch, Robert J.	pl
dc.description.number	23	pl
dc.description.physical	11628-11633	pl
dc.description.volume	85	pl
dc.identifier.doi	10.1021/ac403035a	pl
dc.identifier.eissn	1520-6882	pl
dc.identifier.issn	0003-2700	pl
dc.identifier.uri	http://ruj.uj.edu.pl/xmlui/handle/item/11128
dc.language	eng	pl
dc.language.container	eng	pl
dc.rights	Dodaję tylko opis bibliograficzny	*
dc.rights.licence	Bez licencji otwartego dostępu
dc.rights.uri		*
dc.subtype	Article	pl
dc.title	Computed molecular depth profile for $C_{60}$ bombardment of a molecular solid	pl
dc.title.journal	Analytical Chemistry	pl
dc.type	JournalArticle	pl
dspace.entity.type	Publication

dc.abstract.enpl

Molecular dynamics (MD) simulations have been performed for 10 keV $C_{60}$ bombardment of an octane molecular solid at normal incidence. The results are analyzed using the steady-state statistical sputtering model (SS-SSM) to understand the nature of molecular motions and to predict a depth profile of a $\delta$-layer. The octane system has sputtering yield of $\sim$ 150 $nm^{3}$ of which 85% is in intact molecules and 15% is fragmented species. The main displacement mechanism is along the crater edge. Displacements between layers beneath the impact point are difficult because the nonspherically shaped octane molecule needs a relatively large volume to move into and the molecule needs to be aligned properly for the displacement. Since interlayer mixing is difficult, the predicted depth profile is dominated by the rms roughness and the large information depth because of the large sputtering yield.

dc.affiliationpl

Wydział Fizyki, Astronomii i Informatyki Stosowanej : Instytut Fizyki im. Mariana Smoluchowskiego

dc.contributor.authorpl

Paruch, Robert J.

dc.contributor.authorpl

Garrison, Barbara J.

dc.contributor.authorpl

Postawa, Zbigniew - 100132

dc.date.accessioned

2015-07-02T08:03:32Z

dc.date.available

2015-07-02T08:03:32Z

dc.date.issuedpl

2013

dc.description.adminpl

[AA] Paruch, Robert J.

dc.description.numberpl

23

dc.description.physicalpl

11628-11633

dc.description.volumepl

85

dc.identifier.doipl

10.1021/ac403035a

dc.identifier.eissnpl

1520-6882

dc.identifier.issnpl

0003-2700

dc.identifier.uri

http://ruj.uj.edu.pl/xmlui/handle/item/11128

dc.languagepl

eng

dc.language.containerpl

eng

dc.rights*

Dodaję tylko opis bibliograficzny

dc.rights.licence

Bez licencji otwartego dostępu

dc.rights.uri*

dc.subtypepl

Article

dc.titlepl

Computed molecular depth profile for $C_{60}$ bombardment of a molecular solid

dc.title.journalpl

Analytical Chemistry

dc.typepl

JournalArticle

dspace.entity.type

Publication

Affiliations

Wydział Fizyki, Astronomii i Informatyki Stosowanej

Postawa, Zbigniew

No affiliation

Paruch, Robert J.

Garrison, Barbara J.

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