Structural and magnetic resonance study of astralen nanoparticles

A. I. Shames; E. A. Katz; A. M. Panich; D. Mogilyansky; E. Mogilko; J. Grinblat; V. P. Belousov; I. M. Belousova; A. N. Ponomarev

doi:10.1016/j.diamond.2008.10.056

Structural and magnetic resonance study of astralen nanoparticles

A. I. Shames, E. A. Katz, A. M. Panich, D. Mogilyansky, E. Mogilko, J. Grinblat, V. P. Belousov, I. M. Belousova, A. N. Ponomarev

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

37 Scopus citations

Abstract

Using HRTEM, XRD and Raman spectroscopy we demonstrated a polyhedral multi-shell fullerene-like structure of astralen particles. The polyhedra consist of large defect-free flat graphitic faces connected by defective edge regions with presumably pentagon-like structure. The faces comprise a stacking of 20-50 planar graphene sheets with inter-sheet distance of ~ 0.340 nm. Average sizes of the particles and their flat faces are of ~ 40 nm and ~ 15 nm, respectively. EPR spectra of astralen powder reveal two components: a very broad signal with ΔH_pp > 1 T and an asymmetric narrow one centered close to g = 2.0. The latter consists of two overlapping Lorentzian lines. All spectral components are independent of the ambient pressure. The intensities of all EPR signals show no changes on decreasing temperature from T = 300 K down to 4 K demonstrating the Pauli paramagnetism. Temperature dependent ¹³C NMR measurements yield nuclear spin-lattice relaxation times T_1n ~ T^{- 0.612}. The exponent in the temperature T_1n(T)-dependence for astralen falls between the metallic behavior, T_1n ~ T^{- 1} (Korringa relation), and the semiconductor behavior, T_1n ~ T^{- 0.5}. The unusual magnetic resonance features are attributed to delocalized charge carriers which amount considerably exceeds that of spins localized in defects on astralen edges.

Original language	English
Pages (from-to)	505-510
Number of pages	6
Journal	Diamond and Related Materials
Volume	18
Issue number	2-3
DOIs	https://doi.org/10.1016/j.diamond.2008.10.056
State	Published - 1 Feb 2009

Keywords

Carbon nanoparticles
Magnetic resonance
Multi-shell polyhedra

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
General Chemistry
Mechanical Engineering
Materials Chemistry
Electrical and Electronic Engineering

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10.1016/j.diamond.2008.10.056

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title = "Structural and magnetic resonance study of astralen nanoparticles",

abstract = "Using HRTEM, XRD and Raman spectroscopy we demonstrated a polyhedral multi-shell fullerene-like structure of astralen particles. The polyhedra consist of large defect-free flat graphitic faces connected by defective edge regions with presumably pentagon-like structure. The faces comprise a stacking of 20-50 planar graphene sheets with inter-sheet distance of \textasciitilde{} 0.340 nm. Average sizes of the particles and their flat faces are of \textasciitilde{} 40 nm and \textasciitilde{} 15 nm, respectively. EPR spectra of astralen powder reveal two components: a very broad signal with ΔHpp > 1 T and an asymmetric narrow one centered close to g = 2.0. The latter consists of two overlapping Lorentzian lines. All spectral components are independent of the ambient pressure. The intensities of all EPR signals show no changes on decreasing temperature from T = 300 K down to 4 K demonstrating the Pauli paramagnetism. Temperature dependent 13C NMR measurements yield nuclear spin-lattice relaxation times T1n \textasciitilde{} T- 0.612. The exponent in the temperature T1n(T)-dependence for astralen falls between the metallic behavior, T1n \textasciitilde{} T- 1 (Korringa relation), and the semiconductor behavior, T1n \textasciitilde{} T- 0.5. The unusual magnetic resonance features are attributed to delocalized charge carriers which amount considerably exceeds that of spins localized in defects on astralen edges.",

keywords = "Carbon nanoparticles, Magnetic resonance, Multi-shell polyhedra",

author = "Shames, \{A. I.\} and Katz, \{E. A.\} and Panich, \{A. M.\} and D. Mogilyansky and E. Mogilko and J. Grinblat and Belousov, \{V. P.\} and Belousova, \{I. M.\} and Ponomarev, \{A. N.\}",

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doi = "10.1016/j.diamond.2008.10.056",

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journal = "Diamond and Related Materials",

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TY - JOUR

T1 - Structural and magnetic resonance study of astralen nanoparticles

AU - Shames, A. I.

AU - Katz, E. A.

AU - Panich, A. M.

AU - Mogilyansky, D.

AU - Mogilko, E.

AU - Grinblat, J.

AU - Belousov, V. P.

AU - Belousova, I. M.

AU - Ponomarev, A. N.

PY - 2009/2/1

Y1 - 2009/2/1

N2 - Using HRTEM, XRD and Raman spectroscopy we demonstrated a polyhedral multi-shell fullerene-like structure of astralen particles. The polyhedra consist of large defect-free flat graphitic faces connected by defective edge regions with presumably pentagon-like structure. The faces comprise a stacking of 20-50 planar graphene sheets with inter-sheet distance of ~ 0.340 nm. Average sizes of the particles and their flat faces are of ~ 40 nm and ~ 15 nm, respectively. EPR spectra of astralen powder reveal two components: a very broad signal with ΔHpp > 1 T and an asymmetric narrow one centered close to g = 2.0. The latter consists of two overlapping Lorentzian lines. All spectral components are independent of the ambient pressure. The intensities of all EPR signals show no changes on decreasing temperature from T = 300 K down to 4 K demonstrating the Pauli paramagnetism. Temperature dependent 13C NMR measurements yield nuclear spin-lattice relaxation times T1n ~ T- 0.612. The exponent in the temperature T1n(T)-dependence for astralen falls between the metallic behavior, T1n ~ T- 1 (Korringa relation), and the semiconductor behavior, T1n ~ T- 0.5. The unusual magnetic resonance features are attributed to delocalized charge carriers which amount considerably exceeds that of spins localized in defects on astralen edges.

AB - Using HRTEM, XRD and Raman spectroscopy we demonstrated a polyhedral multi-shell fullerene-like structure of astralen particles. The polyhedra consist of large defect-free flat graphitic faces connected by defective edge regions with presumably pentagon-like structure. The faces comprise a stacking of 20-50 planar graphene sheets with inter-sheet distance of ~ 0.340 nm. Average sizes of the particles and their flat faces are of ~ 40 nm and ~ 15 nm, respectively. EPR spectra of astralen powder reveal two components: a very broad signal with ΔHpp > 1 T and an asymmetric narrow one centered close to g = 2.0. The latter consists of two overlapping Lorentzian lines. All spectral components are independent of the ambient pressure. The intensities of all EPR signals show no changes on decreasing temperature from T = 300 K down to 4 K demonstrating the Pauli paramagnetism. Temperature dependent 13C NMR measurements yield nuclear spin-lattice relaxation times T1n ~ T- 0.612. The exponent in the temperature T1n(T)-dependence for astralen falls between the metallic behavior, T1n ~ T- 1 (Korringa relation), and the semiconductor behavior, T1n ~ T- 0.5. The unusual magnetic resonance features are attributed to delocalized charge carriers which amount considerably exceeds that of spins localized in defects on astralen edges.

KW - Carbon nanoparticles

KW - Magnetic resonance

KW - Multi-shell polyhedra

UR - https://www.scopus.com/pages/publications/59849112542

U2 - 10.1016/j.diamond.2008.10.056

DO - 10.1016/j.diamond.2008.10.056

M3 - Article

AN - SCOPUS:59849112542

SN - 0925-9635

VL - 18

SP - 505

EP - 510

JO - Diamond and Related Materials

JF - Diamond and Related Materials

IS - 2-3

ER -

Structural and magnetic resonance study of astralen nanoparticles

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