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Growth of nanotubes on zirconium in glycerol/fluoride electrolytes

Identifieur interne : 001172 ( PascalFrancis/Corpus ); précédent : 001171; suivant : 001173

Growth of nanotubes on zirconium in glycerol/fluoride electrolytes

Auteurs : F. Muratore ; A. Baron-Wiechec ; T. Hashimoto ; A. Gholinia ; P. Skeldon ; G. E. Thompson

Source :

RBID : Pascal:12-0325080

Descripteurs français

English descriptors

Abstract

The study examines anodic films formed on bulk and sputtered zirconium in ammonium fluoride/glycerol electrolyte with up to 5 vol.% added water, using film cross-sections prepared by focused ion beam and ultramicrotomy. The findings indicate porous films consisting of zirconium fluoride surrounding zirconia-based nanotubes. The fluoride arises due to faster migration of F- ions relative to O2- ions; its dissolution exposes the nanotubes. Ion beam analyses revealed the highest amount of fluorine for films formed in electrolyte with no water addition. 18O tracer indicated that water was the primary source of oxygen in the films, which grew at an efficiency of ∼80%.

Notice en format standard (ISO 2709)

Pour connaître la documentation sur le format Inist Standard.

pA  
A01 01  1    @0 0013-4686
A02 01      @0 ELCAAV
A03   1    @0 Electrochim. acta
A05       @2 56
A06       @2 28
A08 01  1  ENG  @1 Growth of nanotubes on zirconium in glycerol/fluoride electrolytes
A09 01  1  ENG  @1 Electrochemistry from Biology to Physics
A11 01  1    @1 MURATORE (F.)
A11 02  1    @1 BARON-WIECHEC (A.)
A11 03  1    @1 HASHIMOTO (T.)
A11 04  1    @1 GHOLINIA (A.)
A11 05  1    @1 SKELDON (P.)
A11 06  1    @1 THOMPSON (G. E.)
A12 01  1    @1 BERGEL (A.) @9 ed.
A12 02  1    @1 BOND (A. M.) @9 ed.
A12 03  1    @1 BRANKOVIC (S.) @9 ed.
A12 04  1    @1 BULTEL (Y.) @9 ed.
A12 05  1    @1 DI QUARTO (F.) @9 ed.
A12 06  1    @1 GORTON (L.) @9 ed.
A12 07  1    @1 INZELT (G.) @9 ed.
A12 08  1    @1 LAPICQUE (F.) @9 ed.
A12 09  1    @1 LISDAT (F.) @9 ed.
A12 10  1    @1 OPALLO (M.) @9 ed.
A12 11  1    @1 SAVINOVA (E. R.) @9 ed.
A12 12  1    @1 TOH (C.S.) @9 ed.
A12 13  1    @1 TSIRLINA (G. A.) @9 ed.
A12 14  1    @1 VIVIER (V.) @9 ed.
A12 15  1    @1 WINTER (M.) @9 ed.
A14 01      @1 Corrosion and Protection Centre, School of Materials, The University of Manchester, Sackville St. @2 Manchester M13 9PL @3 GBR @Z 1 aut. @Z 2 aut. @Z 3 aut. @Z 4 aut. @Z 5 aut. @Z 6 aut.
A15 01      @1 CNRS @2 Toulouse @3 FRA @Z 1 aut.
A15 02      @1 Monash University @2 Clayton, Vic. @3 AUS @Z 2 aut.
A15 03      @1 University of Houston @2 Houston, TX @3 USA @Z 3 aut.
A15 04      @1 LEPMI @2 Grenoble @3 FRA @Z 4 aut.
A15 05      @1 University of Palermo @3 ITA @Z 5 aut.
A15 06      @1 Lund University @3 SWE @Z 6 aut.
A15 07      @1 Eotvos Lorand University @2 Budapest @3 HUN @Z 7 aut.
A15 08      @1 CNRS @2 Nancy @3 FRA @Z 8 aut.
A15 09      @1 Wildau University @3 DEU @Z 9 aut.
A15 10      @1 Polish Academy of Sciences @2 Warsaw @3 POL @Z 10 aut.
A15 11      @1 Université de Strasbourg @3 FRA @Z 11 aut.
A15 12      @1 Nanyang Technological University @3 SGP @Z 12 aut.
A15 13      @1 Moscow State University @3 RUS @Z 13 aut.
A15 14      @1 Université Pierre et Marie Curie @2 Paris @3 FRA @Z 14 aut.
A15 15      @1 University of Münster @3 DEU @Z 15 aut.
A18 01  1    @1 International Society of Electrochemistry (ISE) @2 1004 Lausanne @3 CHE @9 org-cong.
A20       @1 10500-10506
A21       @1 2011
A23 01      @0 ENG
A43 01      @1 INIST @2 1516 @5 354000505919820250
A44       @0 0000 @1 © 2012 INIST-CNRS. All rights reserved.
A45       @0 34 ref.
A47 01  1    @0 12-0325080
A60       @1 P @2 C
A61       @0 A
A64 01  1    @0 Electrochimica acta
A66 01      @0 GBR
C01 01    ENG  @0 The study examines anodic films formed on bulk and sputtered zirconium in ammonium fluoride/glycerol electrolyte with up to 5 vol.% added water, using film cross-sections prepared by focused ion beam and ultramicrotomy. The findings indicate porous films consisting of zirconium fluoride surrounding zirconia-based nanotubes. The fluoride arises due to faster migration of F- ions relative to O2- ions; its dissolution exposes the nanotubes. Ion beam analyses revealed the highest amount of fluorine for films formed in electrolyte with no water addition. 18O tracer indicated that water was the primary source of oxygen in the films, which grew at an efficiency of ∼80%.
C02 01  3    @0 001B80A07D
C03 01  X  FRE  @0 Ammonium Fluorure @1 SOL @2 NC @2 NA @2 FX @5 01
C03 01  X  ENG  @0 Ammonium Fluorides @1 SOL @2 NC @2 NA @2 FX @5 01
C03 01  X  SPA  @0 Amonio Fluoruro @1 SOL @2 NC @2 NA @2 FX @5 01
C03 02  3  FRE  @0 Nanotube @5 02
C03 02  3  ENG  @0 Nanotubes @5 02
C03 03  3  FRE  @0 Zirconium @2 NC @5 03
C03 03  3  ENG  @0 Zirconium @2 NC @5 03
C03 04  3  FRE  @0 Glycérol @1 SOL @2 NK @5 04
C03 04  3  ENG  @0 Glycerol @1 SOL @2 NK @5 04
C03 05  3  FRE  @0 Anodisation @5 05
C03 05  3  ENG  @0 Anodizing @5 05
C03 06  3  FRE  @0 Microscopie électronique transmission @5 06
C03 06  3  ENG  @0 Transmission electron microscopy @5 06
C03 07  3  FRE  @0 Oxyde anodique @5 07
C03 07  3  ENG  @0 Anodic oxide @5 07
C03 08  X  FRE  @0 Faisceau ionique @5 08
C03 08  X  ENG  @0 Ion beam @5 08
C03 08  X  SPA  @0 Haz iónico @5 08
C03 09  3  FRE  @0 Microscopie électronique balayage @5 09
C03 09  3  ENG  @0 Scanning electron microscopy @5 09
C03 10  3  FRE  @0 Microscopie électronique @5 10
C03 10  3  ENG  @0 Electron microscopy @5 10
C03 11  3  FRE  @0 RBS @5 11
C03 11  3  ENG  @0 RBS @5 11
C03 12  3  FRE  @0 Analyse réaction nucléaire @5 12
C03 12  3  ENG  @0 Nuclear reaction analysis @5 12
C03 13  3  FRE  @0 Morphologie @5 32
C03 13  3  ENG  @0 Morphology @5 32
C03 14  3  FRE  @0 Structure surface @5 33
C03 14  3  ENG  @0 Surface structure @5 33
C03 15  3  FRE  @0 8107D @2 PAC @4 INC @5 76
C07 01  3  FRE  @0 Métal transition @5 53
C07 01  3  ENG  @0 Transition elements @5 53
N21       @1 247
pR  
A30 01  1  ENG  @1 International Society of Electrochemistry (ISE) Meeting @2 61 @3 Nice FRA @4 2010-09-26

Format Inist (serveur)

NO : PASCAL 12-0325080 INIST
ET : Growth of nanotubes on zirconium in glycerol/fluoride electrolytes
AU : MURATORE (F.); BARON-WIECHEC (A.); HASHIMOTO (T.); GHOLINIA (A.); SKELDON (P.); THOMPSON (G. E.); BERGEL (A.); BOND (A. M.); BRANKOVIC (S.); BULTEL (Y.); DI QUARTO (F.); GORTON (L.); INZELT (G.); LAPICQUE (F.); LISDAT (F.); OPALLO (M.); SAVINOVA (E. R.); TOH (C.S.); TSIRLINA (G. A.); VIVIER (V.); WINTER (M.)
AF : Corrosion and Protection Centre, School of Materials, The University of Manchester, Sackville St./Manchester M13 9PL/Royaume-Uni (1 aut., 2 aut., 3 aut., 4 aut., 5 aut., 6 aut.); CNRS/Toulouse/France (1 aut.); Monash University/Clayton, Vic./Australie (2 aut.); University of Houston/Houston, TX/Etats-Unis (3 aut.); LEPMI/Grenoble/France (4 aut.); University of Palermo/Italie (5 aut.); Lund University/Suède (6 aut.); Eotvos Lorand University/Budapest/Hongrie (7 aut.); CNRS/Nancy/France (8 aut.); Wildau University/Allemagne (9 aut.); Polish Academy of Sciences/Warsaw/Pologne (10 aut.); Université de Strasbourg/France (11 aut.); Nanyang Technological University/Singapour (12 aut.); Moscow State University/Russie (13 aut.); Université Pierre et Marie Curie/Paris/France (14 aut.); University of Münster/Allemagne (15 aut.)
DT : Publication en série; Congrès; Niveau analytique
SO : Electrochimica acta; ISSN 0013-4686; Coden ELCAAV; Royaume-Uni; Da. 2011; Vol. 56; No. 28; Pp. 10500-10506; Bibl. 34 ref.
LA : Anglais
EA : The study examines anodic films formed on bulk and sputtered zirconium in ammonium fluoride/glycerol electrolyte with up to 5 vol.% added water, using film cross-sections prepared by focused ion beam and ultramicrotomy. The findings indicate porous films consisting of zirconium fluoride surrounding zirconia-based nanotubes. The fluoride arises due to faster migration of F- ions relative to O2- ions; its dissolution exposes the nanotubes. Ion beam analyses revealed the highest amount of fluorine for films formed in electrolyte with no water addition. 18O tracer indicated that water was the primary source of oxygen in the films, which grew at an efficiency of ∼80%.
CC : 001B80A07D
FD : Ammonium Fluorure; Nanotube; Zirconium; Glycérol; Anodisation; Microscopie électronique transmission; Oxyde anodique; Faisceau ionique; Microscopie électronique balayage; Microscopie électronique; RBS; Analyse réaction nucléaire; Morphologie; Structure surface; 8107D
FG : Métal transition
ED : Ammonium Fluorides; Nanotubes; Zirconium; Glycerol; Anodizing; Transmission electron microscopy; Anodic oxide; Ion beam; Scanning electron microscopy; Electron microscopy; RBS; Nuclear reaction analysis; Morphology; Surface structure
EG : Transition elements
SD : Amonio Fluoruro; Haz iónico
LO : INIST-1516.354000505919820250
ID : 12-0325080

Links to Exploration step

Pascal:12-0325080

Le document en format XML

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<term>Electron microscopy</term>
<term>Glycerol</term>
<term>Ion beam</term>
<term>Morphology</term>
<term>Nanotubes</term>
<term>Nuclear reaction analysis</term>
<term>RBS</term>
<term>Scanning electron microscopy</term>
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<div type="abstract" xml:lang="en">The study examines anodic films formed on bulk and sputtered zirconium in ammonium fluoride/glycerol electrolyte with up to 5 vol.% added water, using film cross-sections prepared by focused ion beam and ultramicrotomy. The findings indicate porous films consisting of zirconium fluoride surrounding zirconia-based nanotubes. The fluoride arises due to faster migration of F
<sup>-</sup>
ions relative to O
<sup>2-</sup>
ions; its dissolution exposes the nanotubes. Ion beam analyses revealed the highest amount of fluorine for films formed in electrolyte with no water addition.
<sup>18</sup>
O tracer indicated that water was the primary source of oxygen in the films, which grew at an efficiency of ∼80%.</div>
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</fA12>
<fA12 i1="05" i2="1">
<s1>DI QUARTO (F.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="06" i2="1">
<s1>GORTON (L.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="07" i2="1">
<s1>INZELT (G.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="08" i2="1">
<s1>LAPICQUE (F.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="09" i2="1">
<s1>LISDAT (F.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="10" i2="1">
<s1>OPALLO (M.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="11" i2="1">
<s1>SAVINOVA (E. R.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="12" i2="1">
<s1>TOH (C.S.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="13" i2="1">
<s1>TSIRLINA (G. A.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="14" i2="1">
<s1>VIVIER (V.)</s1>
<s9>ed.</s9>
</fA12>
<fA12 i1="15" i2="1">
<s1>WINTER (M.)</s1>
<s9>ed.</s9>
</fA12>
<fA14 i1="01">
<s1>Corrosion and Protection Centre, School of Materials, The University of Manchester, Sackville St.</s1>
<s2>Manchester M13 9PL</s2>
<s3>GBR</s3>
<sZ>1 aut.</sZ>
<sZ>2 aut.</sZ>
<sZ>3 aut.</sZ>
<sZ>4 aut.</sZ>
<sZ>5 aut.</sZ>
<sZ>6 aut.</sZ>
</fA14>
<fA15 i1="01">
<s1>CNRS</s1>
<s2>Toulouse</s2>
<s3>FRA</s3>
<sZ>1 aut.</sZ>
</fA15>
<fA15 i1="02">
<s1>Monash University</s1>
<s2>Clayton, Vic.</s2>
<s3>AUS</s3>
<sZ>2 aut.</sZ>
</fA15>
<fA15 i1="03">
<s1>University of Houston</s1>
<s2>Houston, TX</s2>
<s3>USA</s3>
<sZ>3 aut.</sZ>
</fA15>
<fA15 i1="04">
<s1>LEPMI</s1>
<s2>Grenoble</s2>
<s3>FRA</s3>
<sZ>4 aut.</sZ>
</fA15>
<fA15 i1="05">
<s1>University of Palermo</s1>
<s3>ITA</s3>
<sZ>5 aut.</sZ>
</fA15>
<fA15 i1="06">
<s1>Lund University</s1>
<s3>SWE</s3>
<sZ>6 aut.</sZ>
</fA15>
<fA15 i1="07">
<s1>Eotvos Lorand University</s1>
<s2>Budapest</s2>
<s3>HUN</s3>
<sZ>7 aut.</sZ>
</fA15>
<fA15 i1="08">
<s1>CNRS</s1>
<s2>Nancy</s2>
<s3>FRA</s3>
<sZ>8 aut.</sZ>
</fA15>
<fA15 i1="09">
<s1>Wildau University</s1>
<s3>DEU</s3>
<sZ>9 aut.</sZ>
</fA15>
<fA15 i1="10">
<s1>Polish Academy of Sciences</s1>
<s2>Warsaw</s2>
<s3>POL</s3>
<sZ>10 aut.</sZ>
</fA15>
<fA15 i1="11">
<s1>Université de Strasbourg</s1>
<s3>FRA</s3>
<sZ>11 aut.</sZ>
</fA15>
<fA15 i1="12">
<s1>Nanyang Technological University</s1>
<s3>SGP</s3>
<sZ>12 aut.</sZ>
</fA15>
<fA15 i1="13">
<s1>Moscow State University</s1>
<s3>RUS</s3>
<sZ>13 aut.</sZ>
</fA15>
<fA15 i1="14">
<s1>Université Pierre et Marie Curie</s1>
<s2>Paris</s2>
<s3>FRA</s3>
<sZ>14 aut.</sZ>
</fA15>
<fA15 i1="15">
<s1>University of Münster</s1>
<s3>DEU</s3>
<sZ>15 aut.</sZ>
</fA15>
<fA18 i1="01" i2="1">
<s1>International Society of Electrochemistry (ISE)</s1>
<s2>1004 Lausanne</s2>
<s3>CHE</s3>
<s9>org-cong.</s9>
</fA18>
<fA20>
<s1>10500-10506</s1>
</fA20>
<fA21>
<s1>2011</s1>
</fA21>
<fA23 i1="01">
<s0>ENG</s0>
</fA23>
<fA43 i1="01">
<s1>INIST</s1>
<s2>1516</s2>
<s5>354000505919820250</s5>
</fA43>
<fA44>
<s0>0000</s0>
<s1>© 2012 INIST-CNRS. All rights reserved.</s1>
</fA44>
<fA45>
<s0>34 ref.</s0>
</fA45>
<fA47 i1="01" i2="1">
<s0>12-0325080</s0>
</fA47>
<fA60>
<s1>P</s1>
<s2>C</s2>
</fA60>
<fA61>
<s0>A</s0>
</fA61>
<fA64 i1="01" i2="1">
<s0>Electrochimica acta</s0>
</fA64>
<fA66 i1="01">
<s0>GBR</s0>
</fA66>
<fC01 i1="01" l="ENG">
<s0>The study examines anodic films formed on bulk and sputtered zirconium in ammonium fluoride/glycerol electrolyte with up to 5 vol.% added water, using film cross-sections prepared by focused ion beam and ultramicrotomy. The findings indicate porous films consisting of zirconium fluoride surrounding zirconia-based nanotubes. The fluoride arises due to faster migration of F
<sup>-</sup>
ions relative to O
<sup>2-</sup>
ions; its dissolution exposes the nanotubes. Ion beam analyses revealed the highest amount of fluorine for films formed in electrolyte with no water addition.
<sup>18</sup>
O tracer indicated that water was the primary source of oxygen in the films, which grew at an efficiency of ∼80%.</s0>
</fC01>
<fC02 i1="01" i2="3">
<s0>001B80A07D</s0>
</fC02>
<fC03 i1="01" i2="X" l="FRE">
<s0>Ammonium Fluorure</s0>
<s1>SOL</s1>
<s2>NC</s2>
<s2>NA</s2>
<s2>FX</s2>
<s5>01</s5>
</fC03>
<fC03 i1="01" i2="X" l="ENG">
<s0>Ammonium Fluorides</s0>
<s1>SOL</s1>
<s2>NC</s2>
<s2>NA</s2>
<s2>FX</s2>
<s5>01</s5>
</fC03>
<fC03 i1="01" i2="X" l="SPA">
<s0>Amonio Fluoruro</s0>
<s1>SOL</s1>
<s2>NC</s2>
<s2>NA</s2>
<s2>FX</s2>
<s5>01</s5>
</fC03>
<fC03 i1="02" i2="3" l="FRE">
<s0>Nanotube</s0>
<s5>02</s5>
</fC03>
<fC03 i1="02" i2="3" l="ENG">
<s0>Nanotubes</s0>
<s5>02</s5>
</fC03>
<fC03 i1="03" i2="3" l="FRE">
<s0>Zirconium</s0>
<s2>NC</s2>
<s5>03</s5>
</fC03>
<fC03 i1="03" i2="3" l="ENG">
<s0>Zirconium</s0>
<s2>NC</s2>
<s5>03</s5>
</fC03>
<fC03 i1="04" i2="3" l="FRE">
<s0>Glycérol</s0>
<s1>SOL</s1>
<s2>NK</s2>
<s5>04</s5>
</fC03>
<fC03 i1="04" i2="3" l="ENG">
<s0>Glycerol</s0>
<s1>SOL</s1>
<s2>NK</s2>
<s5>04</s5>
</fC03>
<fC03 i1="05" i2="3" l="FRE">
<s0>Anodisation</s0>
<s5>05</s5>
</fC03>
<fC03 i1="05" i2="3" l="ENG">
<s0>Anodizing</s0>
<s5>05</s5>
</fC03>
<fC03 i1="06" i2="3" l="FRE">
<s0>Microscopie électronique transmission</s0>
<s5>06</s5>
</fC03>
<fC03 i1="06" i2="3" l="ENG">
<s0>Transmission electron microscopy</s0>
<s5>06</s5>
</fC03>
<fC03 i1="07" i2="3" l="FRE">
<s0>Oxyde anodique</s0>
<s5>07</s5>
</fC03>
<fC03 i1="07" i2="3" l="ENG">
<s0>Anodic oxide</s0>
<s5>07</s5>
</fC03>
<fC03 i1="08" i2="X" l="FRE">
<s0>Faisceau ionique</s0>
<s5>08</s5>
</fC03>
<fC03 i1="08" i2="X" l="ENG">
<s0>Ion beam</s0>
<s5>08</s5>
</fC03>
<fC03 i1="08" i2="X" l="SPA">
<s0>Haz iónico</s0>
<s5>08</s5>
</fC03>
<fC03 i1="09" i2="3" l="FRE">
<s0>Microscopie électronique balayage</s0>
<s5>09</s5>
</fC03>
<fC03 i1="09" i2="3" l="ENG">
<s0>Scanning electron microscopy</s0>
<s5>09</s5>
</fC03>
<fC03 i1="10" i2="3" l="FRE">
<s0>Microscopie électronique</s0>
<s5>10</s5>
</fC03>
<fC03 i1="10" i2="3" l="ENG">
<s0>Electron microscopy</s0>
<s5>10</s5>
</fC03>
<fC03 i1="11" i2="3" l="FRE">
<s0>RBS</s0>
<s5>11</s5>
</fC03>
<fC03 i1="11" i2="3" l="ENG">
<s0>RBS</s0>
<s5>11</s5>
</fC03>
<fC03 i1="12" i2="3" l="FRE">
<s0>Analyse réaction nucléaire</s0>
<s5>12</s5>
</fC03>
<fC03 i1="12" i2="3" l="ENG">
<s0>Nuclear reaction analysis</s0>
<s5>12</s5>
</fC03>
<fC03 i1="13" i2="3" l="FRE">
<s0>Morphologie</s0>
<s5>32</s5>
</fC03>
<fC03 i1="13" i2="3" l="ENG">
<s0>Morphology</s0>
<s5>32</s5>
</fC03>
<fC03 i1="14" i2="3" l="FRE">
<s0>Structure surface</s0>
<s5>33</s5>
</fC03>
<fC03 i1="14" i2="3" l="ENG">
<s0>Surface structure</s0>
<s5>33</s5>
</fC03>
<fC03 i1="15" i2="3" l="FRE">
<s0>8107D</s0>
<s2>PAC</s2>
<s4>INC</s4>
<s5>76</s5>
</fC03>
<fC07 i1="01" i2="3" l="FRE">
<s0>Métal transition</s0>
<s5>53</s5>
</fC07>
<fC07 i1="01" i2="3" l="ENG">
<s0>Transition elements</s0>
<s5>53</s5>
</fC07>
<fN21>
<s1>247</s1>
</fN21>
</pA>
<pR>
<fA30 i1="01" i2="1" l="ENG">
<s1>International Society of Electrochemistry (ISE) Meeting</s1>
<s2>61</s2>
<s3>Nice FRA</s3>
<s4>2010-09-26</s4>
</fA30>
</pR>
</standard>
<server>
<NO>PASCAL 12-0325080 INIST</NO>
<ET>Growth of nanotubes on zirconium in glycerol/fluoride electrolytes</ET>
<AU>MURATORE (F.); BARON-WIECHEC (A.); HASHIMOTO (T.); GHOLINIA (A.); SKELDON (P.); THOMPSON (G. E.); BERGEL (A.); BOND (A. M.); BRANKOVIC (S.); BULTEL (Y.); DI QUARTO (F.); GORTON (L.); INZELT (G.); LAPICQUE (F.); LISDAT (F.); OPALLO (M.); SAVINOVA (E. R.); TOH (C.S.); TSIRLINA (G. A.); VIVIER (V.); WINTER (M.)</AU>
<AF>Corrosion and Protection Centre, School of Materials, The University of Manchester, Sackville St./Manchester M13 9PL/Royaume-Uni (1 aut., 2 aut., 3 aut., 4 aut., 5 aut., 6 aut.); CNRS/Toulouse/France (1 aut.); Monash University/Clayton, Vic./Australie (2 aut.); University of Houston/Houston, TX/Etats-Unis (3 aut.); LEPMI/Grenoble/France (4 aut.); University of Palermo/Italie (5 aut.); Lund University/Suède (6 aut.); Eotvos Lorand University/Budapest/Hongrie (7 aut.); CNRS/Nancy/France (8 aut.); Wildau University/Allemagne (9 aut.); Polish Academy of Sciences/Warsaw/Pologne (10 aut.); Université de Strasbourg/France (11 aut.); Nanyang Technological University/Singapour (12 aut.); Moscow State University/Russie (13 aut.); Université Pierre et Marie Curie/Paris/France (14 aut.); University of Münster/Allemagne (15 aut.)</AF>
<DT>Publication en série; Congrès; Niveau analytique</DT>
<SO>Electrochimica acta; ISSN 0013-4686; Coden ELCAAV; Royaume-Uni; Da. 2011; Vol. 56; No. 28; Pp. 10500-10506; Bibl. 34 ref.</SO>
<LA>Anglais</LA>
<EA>The study examines anodic films formed on bulk and sputtered zirconium in ammonium fluoride/glycerol electrolyte with up to 5 vol.% added water, using film cross-sections prepared by focused ion beam and ultramicrotomy. The findings indicate porous films consisting of zirconium fluoride surrounding zirconia-based nanotubes. The fluoride arises due to faster migration of F
<sup>-</sup>
ions relative to O
<sup>2-</sup>
ions; its dissolution exposes the nanotubes. Ion beam analyses revealed the highest amount of fluorine for films formed in electrolyte with no water addition.
<sup>18</sup>
O tracer indicated that water was the primary source of oxygen in the films, which grew at an efficiency of ∼80%.</EA>
<CC>001B80A07D</CC>
<FD>Ammonium Fluorure; Nanotube; Zirconium; Glycérol; Anodisation; Microscopie électronique transmission; Oxyde anodique; Faisceau ionique; Microscopie électronique balayage; Microscopie électronique; RBS; Analyse réaction nucléaire; Morphologie; Structure surface; 8107D</FD>
<FG>Métal transition</FG>
<ED>Ammonium Fluorides; Nanotubes; Zirconium; Glycerol; Anodizing; Transmission electron microscopy; Anodic oxide; Ion beam; Scanning electron microscopy; Electron microscopy; RBS; Nuclear reaction analysis; Morphology; Surface structure</ED>
<EG>Transition elements</EG>
<SD>Amonio Fluoruro; Haz iónico</SD>
<LO>INIST-1516.354000505919820250</LO>
<ID>12-0325080</ID>
</server>
</inist>
</record>

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