| People | Locations | Statistics |
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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Bureau, Bruno
University of Rennes
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (126/126 displayed)
- 2024Effect of Bi Additive on the Physical Properties of Ge2Se3-Based Equichalcogenide Glasses and Thin Films
- 2022Broadband Photosensitive Medium Based on Amorphous Equichalcogenidescitations
- 2022The Art of Positronics in Contemporary Nanomaterials Science: A Case Study of Sub-Nanometer Scaled Glassy Arsenoselenidescitations
- 2021Extended aging of Ge-Se glasses below the glass transition temperaturecitations
- 2021Toward Chalcogenide Platform Infrared Sensor Dedicated to the In Situ Detection of Aromatic Hydrocarbons in Natural Waters via an Attenuated Total Reflection Spectroscopy Studycitations
- 2021High-Energy Mechanical Milling-Driven Reamorphization in Glassy Arsenic Monoselenide: On the Path of Tailoring Special Molecular-Network Glassescitations
- 2021High-Energy Mechanical Milling-Driven Reamorphization in Glassy Arsenic Monoselenide: On the Path of Tailoring Special Molecular-Network Glassescitations
- 2020Anodic bonding of mid-infrared transparent germanate glasses for high pressure - high temperature microfluidic applicationscitations
- 2020On the glass transition temperature Tg against molar volume Vm plotting in arsenoselenide glassescitations
- 2020Effect of high-energy mechanical milling on the medium-range ordering in glassy As-Secitations
- 2019Effect of high-energy mechanical milling on the FSDP-related XRPD correlations in Se-rich glassy arsenic selenidescitations
- 2019Structural and chemical homogeneity of chalcogenide glass prepared by melt-rockingcitations
- 2018Infrared-Sensor Based on Selenide Waveguide Devoted to Water Pollution
- 2018Impact of Coinage Metal Insertion on the Thermoelectric Properties of GeTe Solid-State Solutionscitations
- 2018Effect of the Processing Route on the Thermoelectric Performance of Nanostructured CuPbSbTecitations
- 2018Detrimental Effects of Doping Al and Ba on the Thermoelectric Performance of GeTecitations
- 2018Tb<sup>3+</sup> doped Ga<sub>5</sub>Ge<sub>20</sub>Sb<sub>10</sub>Se<sub>65-x</sub>Te<sub>x</sub> (x=0-37.5) chalcogenide glasses and fibers for MWIR and LWIR emissionscitations
- 2018Infrared sulfide fibers for all-optical gas detectioncitations
- 2018Thermoelectric performance of codoped (Bi, In)-GeTe and (Ag, In, Sb)-SnTe materials processed by Spark Plasma Sinteringcitations
- 2018Free-volume structure of glass-As2Se3/PVP nanocomposites prepared by mechanochemical millingcitations
- 2018Te-As-Se glass destabilization using high energy millingcitations
- 2018Optical and thermal properties of Sb/Bi-modified mixed Ge-Ga-Se-Te glassescitations
- 2017Infrared sensor for water pollution and monitoringcitations
- 2017Telluride glasses with far-infrared transmission up to 35 μmcitations
- 2017Chalcogenide glass sensors for bio-molecule detectioncitations
- 2017Theoretical study of an evanescent optical integrated sensor for multipurpose detection of gases and liquids in the Mid-Infraredcitations
- 2017The influence of Sb on glass-forming ability of Ga-containing As2Se3 glassescitations
- 2017Thermoelectric Properties of Highly-Crystallized Ge-Te-Se Glasses Doped with Cu/Bicitations
- 2017Mechanical model of giant photoexpansion in a chalcogenide glass and the role of photofluiditycitations
- 2017Selenide glass fibers for biochemical infrared sensingcitations
- 2016Fiber evanescent wave spectroscopy based on IR fluorescent chalcogenide fiberscitations
- 2016Telluride glass single mode fiber for mid and far infrared filteringcitations
- 2016Structural study by Raman spectroscopy and 77Se NMR of GeSe4 and 80GeSe2–20Ga2Se3 glasses synthesized by mechanical millingcitations
- 2016A novel method for a fast diagnosis of septic arthritis using mid infrared and deported spectroscopycitations
- 2016IR emitting Dy3+ doped chalcogenide fibers for in situ CO2 monitoring in high pressure microsystemscitations
- 2016IR emitting Dy3+ doped chalcogenide fibers for in situ CO2 monitoring in high pressure microsystemscitations
- 2015Surface enhanced infrared absorption by nanoantenna on chalcogenide glass substratescitations
- 2015Surface enhanced infrared absorption by nanoantenna on chalcogenide glass substratescitations
- 2015Electrical and optical investigations in Te–Ge–Ag and Te–Ge–AgI chalcogenide glassescitations
- 2015Structure of Arsenic Selenide Glasses Studied by NMR: Selenium Chain Length Distributions and the Flory Modelcitations
- 2015Influence of P2O5 and Al2O3 content on the structure of erbium-doped borosilicate glasses and on their physical, thermal, optical and luminescence propertiescitations
- 2015A relationship between non-exponential stress relaxation and delayed elasticity in the viscoelastic process in amorphous solids: Illustration on a chalcogenide glasscitations
- 2015A relationship between non-exponential stress relaxation and delayed elasticity in the viscoelastic process in amorphous solids: Illustration on a chalcogenide glasscitations
- 2015Processing and characterization of novel borophosphate glasses and fibers for medical applicationscitations
- 2015Influence of P₂O₅ and Al₂O₃ content on the structure of erbium-doped borosilicate glasses and on their physical, thermal, optical and luminescence properties
- 2015Effect of physical aging on fracture behavior of Te 2 As 3 Se 5 glass fiberscitations
- 2014Te-based glass fiber for far-infrared biochemical sensing up to 16 μmcitations
- 2014Te-based glass fiber for far-infrared biochemical sensing up to 16 μmcitations
- 2014Chalcogenide optical fibers for mid-infrared sensingcitations
- 2014Shaping of looped miniaturized chalcogenide fiber sensing heads for mid-infrared sensingcitations
- 2014Structure of chalcogenide glasses characterized by nuclear magnetic resonance (NMR) spectroscopycitations
- 2014Shaping of looped miniaturized chalcogenide fiber sensing heads for mid-infrared sensingcitations
- 2014A combined 77Se NMR and molecular dynamics contribution to the structural understanding of the chalcogenide glassescitations
- 2014A combined 77Se NMR and molecular dynamics contribution to the structural understanding of the chalcogenide glassescitations
- 2014Chalcogenide microstructured optical fibers for chemical sensingcitations
- 2013RF sputtered amorphous chalcogenide thin films for surface enhanced infrared absorption spectroscopy
- 2013From selenium- to tellurium-based glass optical fibers for infrared spectroscopies.citations
- 2013Chalcogenide Glasses Developed for Optical Micro-sensor Devices
- 2013Comparison between chalcogenide glass single index and microstructured exposed-core fibers for chemical sensingcitations
- 2013Physical properties of the GexSe1 − x glasses in the 0 < x < 0.42 range in correlation with their structurecitations
- 2013Thermoelectric bulk glasses based on the Cu-As-Te-Se systemcitations
- 2013The development of advanced optical fibers for long-wave infrared transmissioncitations
- 2013Mid-IR luminescence of Dy3+ and Pr3+ doped Ga5Ge20Sb10S(Se)(65) bulk glasses and fiberscitations
- 2013Effect of Physical Aging Conditions on the Mechanical Properties of Te2As3Se5 (TAS) Glass Fiberscitations
- 2013The development of advanced optical fibers for long-wave infrared transmissioncitations
- 2012Initial stage of physical ageing in network glassescitations
- 2012Fragile-strong behavior in the AsxSe1-x glass forming system in relation to structural dimensionalitycitations
- 2012Evanescent wave optical micro-sensor based on chalcogenide glasscitations
- 2012Surface enhanced infrared absorption (SEIRA) spectroscopy using gold nanoparticles on As2S3 glasscitations
- 2012Optical sensor based on chalcogenide glasses for IR detection of bio-chemical entities
- 2011Structural characterizations of As-Se-Te glassescitations
- 2011Apatite forming ability and cytocompatibility of pure and Zn-doped bioactive glasses.citations
- 2011Identification of foodborne pathogens within food matrices by IR spectroscopycitations
- 2010Correlation between structure and physical properties of chalcogenide glasses in the AsxSe1-x systemcitations
- 2010Optical microfabrication of tapers in low-loss chalcogenide fiberscitations
- 2010Photoinduced fluidity in chalcogenide glasses at low and high intensities: A model accounting for photon efficiencycitations
- 2010Similar behaviors of sulfide and selenide-based chalcogenide glasses to form glass-ceramicscitations
- 2010Opto-electrophoretic detection of bio-molecules using conducting chalcogenide glass sensors.citations
- 2010An extension of the Czjzek model for the distributions of electric field gradients in disordered solids and an application to NMR spectra of 71Ga in chalcogenide glasses.citations
- 2010An extension of the Czjzek model for the distributions of electric field gradients in disordered solids and an application to NMR spectra of 71Ga in chalcogenide glasses.citations
- 2009Infrared monitoring of underground CO2 storage using chalcogenide glass fiberscitations
- 2009Infrared monitoring of underground CO2 storage using chalcogenide glass fiberscitations
- 2009Rare-earth doped chalcogenide optical waveguide in near and mid-IR for optical potential application
- 2009Rare-earth doped chalcogenide optical waveguide in near and mid-IR for optical potential application
- 2009Correlation Between Thermal and Mechanical Relaxation in Chalcogenide Glass Fiberscitations
- 2009Infrared optical sensor for CO2 detectioncitations
- 2009Infrared optical sensor for CO2 detectioncitations
- 2009Chalcogenide Glass Fibers for Infrared Sensing and Space Opticscitations
- 2009Polymerisation of an industrial resin monitored by infrared fiber evanescent wave spectroscopycitations
- 2009Polymerisation of an industrial resin monitored by infrared fiber evanescent wave spectroscopycitations
- 2009Bimodal phase percolation model for the structure of Ge-Se glasses and the existence of the intermediate phasecitations
- 2009Microstructured chalcogenide fibers for biological and chemical detection: case study: a CO2 sensorcitations
- 2009Chalcogenide Glass Optical Waveguides for Infrared Biosensingcitations
- 2009Chalcogenide Glass Optical Waveguides for Infrared Biosensingcitations
- 2009Influence of ageing conditions on the mechanical properties of Te-As-Se fibrescitations
- 2008Surface plasmon resonance in chalcogenide glass-based optical systemcitations
- 2008Surface plasmon resonance in chalcogenide glass-based optical systemcitations
- 2008Sub-Tg viscoelastic behaviour of chalcogenide glasses, anomalous viscous flow and stress relaxationcitations
- 2008Planar waveguide obtained by burying a Ge22As20Se58 fiber in As2S3 glass
- 2008Frequency upconversion in a Pr3+ doped chalcogenide glass containing silver nanoparticlescitations
- 2008Frequency upconversion in a Pr3+ doped chalcogenide glass containing silver nanoparticlescitations
- 2008Long-term physical ageing in As-Se glasses with short chalcogen chainscitations
- 2008Chemical stability of chalcogenide infrared glass fiberscitations
- 2007Infrared single mode chalcogenide glass fiber for space.citations
- 2007Infrared single mode chalcogenide glass fiber for space.citations
- 2007Room temperature viscosity and delayed elasticity in infrared glass fibercitations
- 2007Chalcogenide waveguide for IR optical rangecitations
- 2007Chalcogenide waveguide for IR optical rangecitations
- 2007New tellurium based glasses for use in bio-sensing applications - art. no. 64330Ucitations
- 2007Infrared Glass-Ceramics With Fine Porous Surfaces for Optical Sensor Applicationscitations
- 2007Crystallization study of infrared transmitting glass ceramics based on GeS2-Sb2S3-CsClcitations
- 2007Crystallization study of infrared transmitting glass ceramics based on GeS2-Sb2S3-CsClcitations
- 2006Infrared biosensors using hydrophobic chalcogenide fibers sensitized with live cellscitations
- 2006Infrared biosensors using hydrophobic chalcogenide fibers sensitized with live cellscitations
- 2006Synthesis, characterization and devitrification behaviour of an yttrium containing boroaluminate glasscitations
- 2006Synthesis, characterization and devitrification behaviour of an yttrium containing boroaluminate glasscitations
- 2004Optical analysis of infrared spectra recorded with tapered chalcogenide glass fiberscitations
- 2004Réalisation d'un capteur à fibre optique infrarouge pour la détection des polluants dans les eaux usées
- 2003New method of preform production for chalcogenide fibres
- 2003New method of preform production for chalcogenide fibres
- 2003A new approach of preform fabrication for chalcogenide fibercitations
- 2003Development of a chalcogenide glass fiber device for in situ pollutant detectioncitations
- 2003Chalcogenide double index fibers: fabrication, design and applications as chemical sensorcitations
- 2003Mechanical properties of a TAS fiber: a preliminary studycitations
- 2002Infrared glass fibers for in-situ sensing, chemical and biochemical reactionscitations
- 2001Biological tissues infrared analysis by chalcogenide glass optical fiber spectroscopycitations
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article
Structure of Arsenic Selenide Glasses Studied by NMR: Selenium Chain Length Distributions and the Flory Model
Abstract
Five homogeneous arsenic selenide glasses with target compositions As 2 Se 3 , AsSe 2 , AsSe 3 , AsSe 4.5 , and AsSe 6 were studied quantitatively by 77 Se Carr−Purcell−Meiboom−Gill magic-angle spinning NMR and transmission electron microscopy−energy-dispersive X-ray spectroscopy. The entire set of NMR spectra is simultaneously fitted with six distinct environments taking into account the effect of first and second neighbors on the position of the 77 Se resonance. The selenium chains are bound at each end to trivalent arsenic atoms, and the chain length distribution can be modeled with the Flory theory, which is well-known in polymer science and is used here for the first time to model the probability of finding each selenium environment in a selenide glass. No arsenic homopolar bond is detected in our experiments. ■ INTRODUCTION Chalcogenide glasses exhibit a wide range of physical properties such as infrared transparency, high refractive indices, and reversible amorphous-to-crystal transitions and can be easily shaped into optical devices. 1−6 Among them, the arsenic selenide glasses As x Se 1−x are considered to be a promising family because glassy As 2 Se 3 is a good candidate for all-optical switching 7 or for use as a mid-infrared laser source; 8 in addition, arsenic selenide glasses can be used for optic fibers. 9 Recent studies also investigated the possibility of preparing these glasses using microwave heating. 10 Numerous attempts were made to draw a link between the changes in the physical properties of arsenic selenide and the evolution of its molecular structure as the arsenic content varies, both at room temperature 11,12 and when the temperature is increased, 13 during aging of the glass, 14 or when irradiated with a laser. 15 To gain some insight into the arsenic selenide glass structures, recent studies relied on molecular dynamics 16−18 combined with anomalous X-ray scattering 19 or 77 Se solid-state NMR 20−23 to characterize the environments and connectivity of selenium and arsenic atoms. Many of these studies hint toward the existence of a small amount of As−As homopolar bond 12,16 with tetravalent arsenic atoms linked to two arsenic and two selenium atoms. 19 Moreover, 77 Se NMR spectroscopy can quantify three distinct selenium environments (selenium atoms linked to two, one, or zero arsenic atoms) and shows that there is some disorder in the distribution of the lengths of the selenium chains that link arsenic atoms together, as opposed to what is inferred in the chain-crossing model (i.e., when the selenium chains are of similar lengths). 20,23 Interestingly, it was suggested that the Flory model, 24 which describes the distribution of chain lengths in organic polymers, could be applied to inorganic polymers (mostly silicates) because the underlying chemical phenomena share striking similarities, especially for glasses with covalent bonds and no ionic species. 25−27 The Flory theory provides a very simple model for the probability, P(n), of finding a chain of length n, which is equal to np n−1 (1 − p) 2 , where p is the probability to form a linkage between two monomers and the average chain length is given by 1 + p/1 − p. Moreover, Flory distributions are characterized by a single parameter p and not two as is the case for Gaussian distributions (which may not correctly reproduce the chain length distributions for arsenic-rich glasses with short chain lengths) or three for skewed Gaussian distributions. Therefore, the Flory framework was applied here as a model for the distribution of chain lengths. 77 Se is a spin 1/2 nucleus with a 7.63% natural abundance, a gyromagnetic ratio equal to 19% of γ(1 H), and a fairly large chemical shift range over 3000 ppm. 28,29 However, as many diluted spin-1/2, it usually features long longitudinal relaxation times around hundreds of seconds, which may affect the measured proportions of each selenium environment. 23 Usually, three selenium environments are distinguished depending upon the nature of the two atoms (arsenic or selenium) they are connected with. 20 However, as the 77 Se atoms are excessively sensitive to their environments, it is often observed that the chemical shifts of these broad lines vary with the composition of the sample, 20 precluding any simultaneous fitting of series of NMR spectra. Such an effect results from a dependence of the