Long-Term Corrosion Testing of Zy-4 in a LiOH Solution under High Pressure and Temperature Conditions

Long-Term Corrosion Testing of Zy-4 in a LiOH Solution under High Pressure and Temperature Conditions

The fuel cladding is one of the most important structural components for maintaining the integrity of a fuel channel and for safely exploitation of a nuclear power plant. The corrosion behavior of a fuel cladding material, Zy-4, under high pressure and temperatures conditions, was analyzed in a stat...

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Main Authors: Diana Diniasi, Florentina Golgovici, Alexandru Horia Marin, Aurelian Denis Negrea, Manuela Fulger, Ioana Demetrescu
Format: Article
Language:English
Published: MDPI AG 2021-08-01
Series:Materials
Subjects:
corrosion/oxidation
zircaloy-4
XPS
EIS
Online Access:https://www.mdpi.com/1996-1944/14/16/4586
id doaj-84a43e8166724fc699c5d0d696b46bf9
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spelling doaj-84a43e8166724fc699c5d0d696b46bf92021-08-26T14:01:07ZengMDPI AGMaterials1996-19442021-08-01144586458610.3390/ma14164586Long-Term Corrosion Testing of Zy-4 in a LiOH Solution under High Pressure and Temperature ConditionsDiana Diniasi0Florentina Golgovici1Alexandru Horia Marin2Aurelian Denis Negrea3Manuela Fulger4Ioana Demetrescu5Institute for Nuclear Research Pitesti, POB 78, Campului Street, No. 1, 115400 Mioveni, RomaniaDepartment of General Chemistry, Faculty of Applied Chemistry and Materials Science, University Politehnica of Bucharest, Splaiul Independentei Street, No. 313, 060042 Bucharest, RomaniaInstitute for Nuclear Research Pitesti, POB 78, Campului Street, No. 1, 115400 Mioveni, RomaniaRegional Center of Research & Development for Materials, Processes and Innovative Products Dedicated to the Automotive Industry (CRC&D-AUTO), University of Pitesti, Doaga Street, No. 11, 110040 Pitesti, RomaniaInstitute for Nuclear Research Pitesti, POB 78, Campului Street, No. 1, 115400 Mioveni, RomaniaDepartment of General Chemistry, Faculty of Applied Chemistry and Materials Science, University Politehnica of Bucharest, Splaiul Independentei Street, No. 313, 060042 Bucharest, RomaniaThe fuel cladding is one of the most important structural components for maintaining the integrity of a fuel channel and for safely exploitation of a nuclear power plant. The corrosion behavior of a fuel cladding material, Zy-4, under high pressure and temperatures conditions, was analyzed in a static isothermal autoclave under simulated primary water conditions—a LiOH solution at 310 °C and 10 MPa for up to 3024 h. After this, the oxides grown on the Zy-4 sample surface were characterized using electrochemical measurements, gravimetric analysis, metallographic analysis, SEM and XPS. The maximum oxide thicknesses evaluated by gravimetric and SEM measurements were in good agreement; both values were around 1.2 µm. The optical light microscopy (OLM) investigations identified the presence of small hydrides uniformly distributed horizontally across the alloy. EIS impedance spectra showed an increase in the oxide impedance for the samples oxidized for a long time. EIS plots has the best fit with an equivalent circuit which illustrated an oxide model that has two oxide layers: an inner oxide layer and outer layer. The EIS results showed that the inner layer was a barrier layer, and the outer layer was a porous layer. Potentiodynamic polarization results demonstrated superior corrosion resistance of the samples tested for longer periods of time. By XPS measurements we identified all five oxidation states of zirconium: Zr<sup>0</sup> located at 178.5 eV; Zr<sup>4+</sup> at 182.8 eV; and the three suboxides, Zr<sup>+</sup>, Zr<sup>2+</sup> and Zr<sup>3+</sup> at 179.7, 180.8 and 181.8 eV, respectively. The determination of Vickers microhardness completed the investigation.https://www.mdpi.com/1996-1944/14/16/4586corrosion/oxidationzircaloy-4XPSEIS
collection DOAJ
language English
format Article
sources DOAJ
author Diana Diniasi
Florentina Golgovici
Alexandru Horia Marin
Aurelian Denis Negrea
Manuela Fulger
Ioana Demetrescu
spellingShingle Diana Diniasi
Florentina Golgovici
Alexandru Horia Marin
Aurelian Denis Negrea
Manuela Fulger
Ioana Demetrescu
Long-Term Corrosion Testing of Zy-4 in a LiOH Solution under High Pressure and Temperature Conditions
Materials
corrosion/oxidation
zircaloy-4
XPS
EIS
author_facet Diana Diniasi
Florentina Golgovici
Alexandru Horia Marin
Aurelian Denis Negrea
Manuela Fulger
Ioana Demetrescu
author_sort Diana Diniasi
title Long-Term Corrosion Testing of Zy-4 in a LiOH Solution under High Pressure and Temperature Conditions
title_short Long-Term Corrosion Testing of Zy-4 in a LiOH Solution under High Pressure and Temperature Conditions
title_full Long-Term Corrosion Testing of Zy-4 in a LiOH Solution under High Pressure and Temperature Conditions
title_fullStr Long-Term Corrosion Testing of Zy-4 in a LiOH Solution under High Pressure and Temperature Conditions
title_full_unstemmed Long-Term Corrosion Testing of Zy-4 in a LiOH Solution under High Pressure and Temperature Conditions
title_sort long-term corrosion testing of zy-4 in a lioh solution under high pressure and temperature conditions
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2021-08-01
description The fuel cladding is one of the most important structural components for maintaining the integrity of a fuel channel and for safely exploitation of a nuclear power plant. The corrosion behavior of a fuel cladding material, Zy-4, under high pressure and temperatures conditions, was analyzed in a static isothermal autoclave under simulated primary water conditions—a LiOH solution at 310 °C and 10 MPa for up to 3024 h. After this, the oxides grown on the Zy-4 sample surface were characterized using electrochemical measurements, gravimetric analysis, metallographic analysis, SEM and XPS. The maximum oxide thicknesses evaluated by gravimetric and SEM measurements were in good agreement; both values were around 1.2 µm. The optical light microscopy (OLM) investigations identified the presence of small hydrides uniformly distributed horizontally across the alloy. EIS impedance spectra showed an increase in the oxide impedance for the samples oxidized for a long time. EIS plots has the best fit with an equivalent circuit which illustrated an oxide model that has two oxide layers: an inner oxide layer and outer layer. The EIS results showed that the inner layer was a barrier layer, and the outer layer was a porous layer. Potentiodynamic polarization results demonstrated superior corrosion resistance of the samples tested for longer periods of time. By XPS measurements we identified all five oxidation states of zirconium: Zr<sup>0</sup> located at 178.5 eV; Zr<sup>4+</sup> at 182.8 eV; and the three suboxides, Zr<sup>+</sup>, Zr<sup>2+</sup> and Zr<sup>3+</sup> at 179.7, 180.8 and 181.8 eV, respectively. The determination of Vickers microhardness completed the investigation.
topic corrosion/oxidation
zircaloy-4
XPS
EIS
url https://www.mdpi.com/1996-1944/14/16/4586
work_keys_str_mv AT dianadiniasi longtermcorrosiontestingofzy4inaliohsolutionunderhighpressureandtemperatureconditions
AT florentinagolgovici longtermcorrosiontestingofzy4inaliohsolutionunderhighpressureandtemperatureconditions
AT alexandruhoriamarin longtermcorrosiontestingofzy4inaliohsolutionunderhighpressureandtemperatureconditions
AT aureliandenisnegrea longtermcorrosiontestingofzy4inaliohsolutionunderhighpressureandtemperatureconditions
AT manuelafulger longtermcorrosiontestingofzy4inaliohsolutionunderhighpressureandtemperatureconditions
AT ioanademetrescu longtermcorrosiontestingofzy4inaliohsolutionunderhighpressureandtemperatureconditions
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