Electronic stopping in ion-fullerene collisions

T.A. Schlathölter; O. Hadjar; R.A. Hoekstra; R.W.H. Morgenstern

Electronic stopping in ion-fullerene collisions

T.A. Schlathölter, O. Hadjar, R.A. Hoekstra, R.W.H. Morgenstern

Research output: Contribution to journal › Article › Academic › peer-review

12 Citations (Scopus)

Abstract

The electronic friction experienced by a multiply charged ion interacting with the valence electrons of a single fullerene is an important aspect of the collision dynamics. It manifests itself in a considerable loss of projectile kinetic energy transferred to the target, resulting in excitation. The latter mainly leads to direct ionization and multifragmentation and can be recognized in specific patterns of the fragmentation spectra. These fingerprints can be used to quantify electronic stopping and to identify its typical properties as known from particle-solid interactions, such as the oscillation of the electronic stopping with the projectile atomic number Z. These essentially many-body effects can therefore be studied in a well-defined system of finite size.

Original language	English
Pages (from-to)	281-287
Number of pages	7
Journal	Applied Physics A: Materials Science & Processing
Volume	72
Issue number	3
Publication status	Published - Mar-2001

Keywords

HIGHLY-CHARGED IONS
SLOW IONS
C-60 FRAGMENTATION
MOLECULAR-IONS
ENERGY-LOSS
IONIZATION
DEPENDENCE
ATOMS
GAS
DISSOCIATION

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title = "Electronic stopping in ion-fullerene collisions",

abstract = "The electronic friction experienced by a multiply charged ion interacting with the valence electrons of a single fullerene is an important aspect of the collision dynamics. It manifests itself in a considerable loss of projectile kinetic energy transferred to the target, resulting in excitation. The latter mainly leads to direct ionization and multifragmentation and can be recognized in specific patterns of the fragmentation spectra. These fingerprints can be used to quantify electronic stopping and to identify its typical properties as known from particle-solid interactions, such as the oscillation of the electronic stopping with the projectile atomic number Z. These essentially many-body effects can therefore be studied in a well-defined system of finite size.",

keywords = "HIGHLY-CHARGED IONS, SLOW IONS, C-60 FRAGMENTATION, MOLECULAR-IONS, ENERGY-LOSS, IONIZATION, DEPENDENCE, ATOMS, GAS, DISSOCIATION",

author = "T.A. Schlath{\"o}lter and O. Hadjar and R.A. Hoekstra and R.W.H. Morgenstern",

year = "2001",

month = mar,

language = "English",

volume = "72",

pages = "281--287",

journal = "Applied Physics A: Materials Science & Processing",

issn = "0947-8396",

publisher = "Springer",

number = "3",

}

TY - JOUR

T1 - Electronic stopping in ion-fullerene collisions

AU - Schlathölter, T.A.

AU - Hadjar, O.

AU - Hoekstra, R.A.

AU - Morgenstern, R.W.H.

PY - 2001/3

Y1 - 2001/3

N2 - The electronic friction experienced by a multiply charged ion interacting with the valence electrons of a single fullerene is an important aspect of the collision dynamics. It manifests itself in a considerable loss of projectile kinetic energy transferred to the target, resulting in excitation. The latter mainly leads to direct ionization and multifragmentation and can be recognized in specific patterns of the fragmentation spectra. These fingerprints can be used to quantify electronic stopping and to identify its typical properties as known from particle-solid interactions, such as the oscillation of the electronic stopping with the projectile atomic number Z. These essentially many-body effects can therefore be studied in a well-defined system of finite size.

AB - The electronic friction experienced by a multiply charged ion interacting with the valence electrons of a single fullerene is an important aspect of the collision dynamics. It manifests itself in a considerable loss of projectile kinetic energy transferred to the target, resulting in excitation. The latter mainly leads to direct ionization and multifragmentation and can be recognized in specific patterns of the fragmentation spectra. These fingerprints can be used to quantify electronic stopping and to identify its typical properties as known from particle-solid interactions, such as the oscillation of the electronic stopping with the projectile atomic number Z. These essentially many-body effects can therefore be studied in a well-defined system of finite size.

KW - HIGHLY-CHARGED IONS

KW - SLOW IONS

KW - C-60 FRAGMENTATION

KW - MOLECULAR-IONS

KW - ENERGY-LOSS

KW - IONIZATION

KW - DEPENDENCE

KW - ATOMS

KW - GAS

KW - DISSOCIATION

M3 - Article

SN - 0947-8396

VL - 72

SP - 281

EP - 287

JO - Applied Physics A: Materials Science & Processing

JF - Applied Physics A: Materials Science & Processing

IS - 3

ER -

Electronic stopping in ion-fullerene collisions

Abstract

Keywords

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