0000000000627378

AUTHOR

Nicolas Stein

showing 12 related works from this author

Morphological and chemical dynamics upon electrochemical cyclic sodiation of electrochromic tungsten oxide coatings extracted by in situ ellipsometry.

2020

The sodiation–desodiation process of sputtered amorphous electrochromic tungsten oxide coatings in an aqueous-based medium was simultaneously monitored over 99 cycles by cyclic voltammetry and in situ spectroscopic ellipsometry. This allowed extracting the evolution of optical and geometrical parameters upon cycling. The resulting electrochemical coloring-bleaching process was dynamically fitted in the 1.8–2.8 eV optical range with a four-phase model including a constrained spline parametrization of the dielectric function. This allows real time access to thickness, surface roughness, and dielectric function of N a x W O 3 . The temporal evolution of the latter in the fully colored state wa…

[PHYS]Physics [physics]Materials sciencebusiness.industryScanning electron microscopeAnalytical chemistryCharge density01 natural sciencesAtomic and Molecular Physics and OpticsAmorphous solid010309 opticsOpticsEllipsometryElectrochromism0103 physical sciencesContent (measure theory)Surface roughnessElectrical and Electronic EngineeringCyclic voltammetrybusinessEngineering (miscellaneous)Applied optics
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Towards enhanced durability of electrochromic WO3 interfaced with liquid or ceramic sodium-based electrolytes

2020

Abstract The reversible intercalation of sodium ion into tungsten oxide WO3 appears as an interesting alternative to hydrogen or lithium ion reduction in order to get the characteristic transition from clear transparent to bluish coloration in electrochromic devices, but it has been comparatively less considered. In order to address further viable all-ceramic devices based on sodium ion intercalation and overcome the issue of WO3 degradation in aqueous media, three configurations of WO3 thin film-based electrochromic half-cells were tested, namely in (i) aqueous acidified Na2SO4 electrolyte, (ii) room temperature ionic liquid BEPipTFSI electrolyte and (iii) aqueous acidified Na2SO4 electrol…

[PHYS]Physics [physics]Materials scienceAqueous solutionGeneral Chemical EngineeringOxide02 engineering and technologyElectrolyte010402 general chemistry021001 nanoscience & nanotechnologyElectrochemistryElectrochromic devices01 natural sciences0104 chemical sciencesAmorphous solid[SHS]Humanities and Social Scienceschemistry.chemical_compoundchemistryChemical engineeringElectrochromismIonic liquidElectrochemistry[CHIM]Chemical Sciences0210 nano-technologyComputingMilieux_MISCELLANEOUS
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Electrodéposition et caractérisations optiques de nanofils de Tellure monocristallins

2018

International audience

[PHYS]Physics [physics][CHIM] Chemical Sciences[CHIM]Chemical SciencesComputingMilieux_MISCELLANEOUS[PHYS] Physics [physics]
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Real-Time ellipsometric spectra without systematics errors

2013

International audience; In real-time measurement, it is difficult to reduce systematic errors on spectra of ellipsometric angles Ψ and Δ by the mean of two measurementsat two analyzer positions with the incidence plane +45° and -45° [1-2]. Generally, the analyzer is mounted on a motorized rotation stage. Therotation of the optical component from -45° to +45° requires few seconds, and this is incompatible with dynamic measurements.

[PHYS]Physics [physics][PHYS] Physics [physics]
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Design of a real-time spectroscopic rotating compensator ellipsometer without systematic errors

2014

6th International Conference on Spectroscopic Ellipsometry (ICSE), Kyoto, JAPAN, MAY 26-31, 2013; International audience; We describe a spectroscopic ellipsometer in the visible domain (400-800 nm) based on a rotating compensator technology using two detectors. The classical analyzer is replaced by a fixed Rochon birefringent beamsplitter which splits the incidence light wave into two perpendicularly polarized waves, one oriented at +45 degrees and the other one at-45 degrees according to the plane of incidence. Both emergent optical signals are analyzed by two identical CCD detectors which are synchronized by an optical encoder fixed on the shaft of the step-by-step motor of the compensato…

Spectrum analyzerMaterials sciencePlane of incidence02 engineering and technology01 natural sciencesSpectral linelaw.invention010309 opticschemistry.chemical_compoundOpticslaw0103 physical sciencesMaterials ChemistryBismuth tellurideRotary encoderBirefringencebusiness.industryDetectorMetals and Alloys[CHIM.MATE]Chemical Sciences/Material chemistrySurfaces and Interfaces021001 nanoscience & nanotechnologySurfaces Coatings and FilmsElectronic Optical and Magnetic Materialschemistry[ CHIM.MATE ] Chemical Sciences/Material chemistry0210 nano-technologybusinessBeam splitterThin Solid Films
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Coloration mechanism of electrochromic Na x WO3 thin films

2019

International audience; The coloration mechanism of tungsten trioxide (WO3) upon insertion of alkali ions is still under debate after several decades of research. This Letter provides new insights into the reversible insertion and coloration mechanisms of Na+ ions in WO3 thin films sputter-deposited on ITO/glass substrates. A unique model based on a constrained spline approach was developed and applied to draw out ε1+iε2 from spectroscopic ellipsometry data from 0.6 to 4.8 eV whatever the state of the electrochromic active layer, i.e. as-deposited, colored or bleached. It is shown that electrochemically intercalated sodium-tungsten trioxide, NaxWO3 (x=0.1, 0.2, 0.35), exhibits an absorption…

010302 applied physicsAlkali ions[PHYS]Physics [physics]Materials sciencebusiness.industry02 engineering and technology021001 nanoscience & nanotechnologyPhotochemistry01 natural sciencesTungsten trioxideAtomic and Molecular Physics and OpticsActive layerIonchemistry.chemical_compoundOpticschemistryElectrochromismAbsorption band0103 physical sciences[CHIM]Chemical SciencesThin film0210 nano-technologybusinessTrioxide
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Data_File_2.csv

2019

Tabulated real (n) and imaginary (k) parts of the complex refraction index of Na0.2WO3 vs energy (eV) and wavelength (nm)

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Data_File_2.csv

2019

Tabulated real (n) and imaginary (k) parts of the complex refraction index of Na0.2WO3 vs energy (eV) and wavelength (nm)

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Data_File_1.csv

2019

Tabulated real (n) and imaginary (k) parts of the complex refraction index of Na0.1WO3 vs energy (eV) and wavelength (nm)

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Data_File_3.csv

2019

Tabulated real (n) and imaginary (k) parts of the complex refraction index of Na0.35WO3 vs energy (eV) and wavelength (nm)

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Data_File_3.csv

2019

Tabulated real (n) and imaginary (k) parts of the complex refraction index of Na0.35WO3 vs energy (eV) and wavelength (nm)

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Data_File_1.csv

2019

Tabulated real (n) and imaginary (k) parts of the complex refraction index of Na0.1WO3 vs energy (eV) and wavelength (nm)

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