Nanostructured cobalt on porous silicon substrate: Structure and magnetic behaviour
Identifieur interne : 000810 ( Main/Exploration ); précédent : 000809; suivant : 000811Nanostructured cobalt on porous silicon substrate: Structure and magnetic behaviour
Auteurs : W. Belkacem [Tunisie] ; N. Mliki [Tunisie] ; R. Belhi [Tunisie] ; W. Saikaly [France] ; B. Yangui [Tunisie]Source :
- physica status solidi (a) [ 1862-6300 ] ; 2007-10.
Descripteurs français
- Pascal (Inist)
- Aimantation, Cobalt, Dépôt phase vapeur, Dépôt sous vide, Effet Kerr magnétooptique, Epaisseur, Hystérésis magnétique, Microscopie électronique balayage, Microscopie électronique transmission, Nanocristal, Nanoparticule, Relation structure propriété, Spectre perte énergie électron, Substrat silicium poreux, Ultravide.
- Wicri :
- topic : Cobalt.
English descriptors
- KwdEn :
- 61.46.Df, 68.37.Hk, 68.37.Lp, 68.55.−a, 75.30.Gw, 75.75.−a, Cobalt, Electron energy loss spectra, Kerr magneto-optical effect, Magnetic hysteresis, Magnetization, Nanocrystal, Nanoparticles, Property structure relationship, Scanning electron microscopy, Thickness, Transmission electron microscopy, Ultrahigh vacuum, Vacuum deposition, Vapor deposition.
Abstract
During an anodization process, porous silicon (PS) consisting of pores with a diameter of about 40 nm and a depth from 5 µm to 40 µm has been produced. To achieve oriented channels in this mesoporous range, a p+‐type Si wafer was electrochemically etched in an aqueous electrolyte of HF. We report the formation, after the anodization step, of a cobalt nanostructure in a porous silicon matrix. Co nanocrystals on and in a porous silicon layer have been prepared by the UHV evaporation technique and characterized by scanning electron microscopy (SEM), transmission electron microscopy (TEM) and electron energy loss spectroscopy (EELS). This technique was performed to show the chemical element distribution within the channels. It is found that the deposition condition is an important factor for obtaining nano‐structures. Initial deposition leads to Co particle penetration in silicon pores whereas subsequent deposition results only in an increase of the thickness at the surface with no further penetration. Additional experiments were carried out by using the magneto‐optical Kerr effect to obtain information about the magnetic properties. The first results show that the magnetic response for layers <5 nm presents an important perpendicular component of magnetization whereas for thicker deposited layers (8 nm < t < 20 nm) the magnetic response seems to act as that of a thin film in which the squareness of the hysteresis loop decreases with increasing film thickness. (© 2007 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)
Url:
DOI: 10.1002/pssa.200622362
Affiliations:
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Le document en format XML
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(a)</title><idno type="ISSN">1862-6300</idno><idno type="eISSN">1862-6319</idno><imprint><publisher>WILEY‐VCH Verlag</publisher><pubPlace>Berlin</pubPlace><date type="published" when="2007-10">2007-10</date><biblScope unit="volume">204</biblScope><biblScope unit="issue">10</biblScope><biblScope unit="page" from="3321">3321</biblScope><biblScope unit="page" to="3332">3332</biblScope></imprint><idno type="ISSN">1862-6300</idno></series><idno type="istex">F728CC01D32889AFEFE306423DCC8A092CF17FC2</idno><idno type="DOI">10.1002/pssa.200622362</idno><idno type="ArticleID">PSSA200622362</idno></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">1862-6300</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>61.46.Df</term><term>68.37.Hk</term><term>68.37.Lp</term><term>68.55.−a</term><term>75.30.Gw</term><term>75.75.−a</term><term>Cobalt</term><term>Electron energy loss spectra</term><term>Kerr magneto-optical effect</term><term>Magnetic hysteresis</term><term>Magnetization</term><term>Nanocrystal</term><term>Nanoparticles</term><term>Property structure relationship</term><term>Scanning electron microscopy</term><term>Thickness</term><term>Transmission electron microscopy</term><term>Ultrahigh vacuum</term><term>Vacuum deposition</term><term>Vapor deposition</term></keywords><keywords scheme="Pascal" xml:lang="fr"><term>Aimantation</term><term>Cobalt</term><term>Dépôt phase vapeur</term><term>Dépôt sous vide</term><term>Effet Kerr magnétooptique</term><term>Epaisseur</term><term>Hystérésis magnétique</term><term>Microscopie électronique balayage</term><term>Microscopie électronique transmission</term><term>Nanocristal</term><term>Nanoparticule</term><term>Relation structure propriété</term><term>Spectre perte énergie électron</term><term>Substrat silicium poreux</term><term>Ultravide</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Cobalt</term></keywords></textClass><langUsage><language ident="en">en</language></langUsage></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">During an anodization process, porous silicon (PS) consisting of pores with a diameter of about 40 nm and a depth from 5 µm to 40 µm has been produced. To achieve oriented channels in this mesoporous range, a p+‐type Si wafer was electrochemically etched in an aqueous electrolyte of HF. We report the formation, after the anodization step, of a cobalt nanostructure in a porous silicon matrix. Co nanocrystals on and in a porous silicon layer have been prepared by the UHV evaporation technique and characterized by scanning electron microscopy (SEM), transmission electron microscopy (TEM) and electron energy loss spectroscopy (EELS). This technique was performed to show the chemical element distribution within the channels. It is found that the deposition condition is an important factor for obtaining nano‐structures. Initial deposition leads to Co particle penetration in silicon pores whereas subsequent deposition results only in an increase of the thickness at the surface with no further penetration. Additional experiments were carried out by using the magneto‐optical Kerr effect to obtain information about the magnetic properties. The first results show that the magnetic response for layers <5 nm presents an important perpendicular component of magnetization whereas for thicker deposited layers (8 nm < t < 20 nm) the magnetic response seems to act as that of a thin film in which the squareness of the hysteresis loop decreases with increasing film thickness. (© 2007 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)</div></front></TEI><affiliations><list><country><li>France</li><li>Tunisie</li></country><region><li>Provence-Alpes-Côte d'Azur</li></region><settlement><li>Marseille</li></settlement></list><tree><country name="Tunisie"><noRegion><name sortKey="Belkacem, W" sort="Belkacem, W" uniqKey="Belkacem W" first="W." last="Belkacem">W. Belkacem</name></noRegion><name sortKey="Belhi, R" sort="Belhi, R" uniqKey="Belhi R" first="R." last="Belhi">R. Belhi</name><name sortKey="Mliki, N" sort="Mliki, N" uniqKey="Mliki N" first="N." last="Mliki">N. Mliki</name><name sortKey="Yangui, B" sort="Yangui, B" uniqKey="Yangui B" first="B." last="Yangui">B. Yangui</name></country><country name="France"><region name="Provence-Alpes-Côte d'Azur"><name sortKey="Saikaly, W" sort="Saikaly, W" uniqKey="Saikaly W" first="W." last="Saikaly">W. Saikaly</name></region></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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