Focusing ultrafast laser pulses induce localized permanent structural modifications on the surface or in transparent materials, that are of particular interest for photonic applications. Among the materials of interest, the tellurite glass family is attractive for near-infrared and photonics applications due to its broad-transparency window and high optical nonlinearity. Here, we systematically investigate structural changes occurring in various TeO2-based glasses exposed to femtosecond laser with various laser parameters. Remarkably, in a regime where heat accumulated after successive pulses, we observed the formation of polarization-controlled self-organized patterns expanding well beyond the focal volume, suggesting the presence of an evanescent coupling mechanism enhancing the self-organization. In addition, our results, obtained with compositional elemental analysis coupled with Raman spectra suggest different ion migration mechanisms in the laser affected zone at the surface and inside the glass. The formation of crystalline tellurium (t-Te) from glass structural units due to photo-induced elemental dissociation was observed only at the surface. The formation of ultrathin layer of crystalline tellurium offers the possibility to explore structural transitions in two-dimensional (2D) glasses by observing changes in the short- and medium- range structural orders, induced by spatial confinement

D. Milanese

D. Pugliese

E. Descrovi

G. Torun

T. Kishi

Y. Bellouard

English

Archivio istituzionale della ricerca - INRIM

12 August 2023ISTITUTO NAZIONALE DI RICERCA METROLOGICARepository IstituzionaleInvestigating femtosecond laser interaction with tellurite glass family / Torun, G.; Kishi, T.; Pugliese, D.;Milanese, D.; Descrovi, E.; Bellouard, Y.. - GOMD S3: Optical and Electronic Materials and Devices -Fundamentals and Applications:(2021). (Intervento presentato al convegno Glass & Optical MaterialsDivision 2021 Annual Meeting (GOMD 2021) tenutosi a Online nel 13-16 Dicembre 2021).OriginalInvestigating femtosecond laser interaction with tellurite glass familyPublisher:PublishedDOI:Terms of use:Publisher copyright(Article begins on next page)This article is made available under terms and conditions as specified in the corresponding bibliographicdescription in the repositoryAvailability:This version is available at: 11696/77278 since:The American Ceramic Society*Denotes Presenter 2021 PACRIM/GOMD Conference 173Abstracts2:30 PM(GOMD-185-2021) Investigating femtosecond laser interaction with tellurite glass familyG. Torun*1; T. Kishi3; D. Pugliese2; D. Milanese4; E. Descrovi2; Y. Bellouard11. EPFL, Switzerland2. Politecnico di Torino, Department of Applied Science and Technology and RU INSTM, Italy3. Tokyo Institute of Technology, Department of Chemistry and Materials Science, Japan4. Università di Parma, Department of Engineering and Architecture and RU INSTM, ItalyFocusing ultrafast laser pulses induce localized permanent structural modifications on the surface or in transparent materials, that are of particular interest for photonic applications. Among the materials of interest, the tellurite glass family is attractive for near-infrared and photonics applications due to its broad-transparency window and high optical nonlinearity. Here, we systematically investigate struc-tural changes occurring in various TeO2-based glasses exposed to femtosecond laser with various laser parameters. Remarkably, in a regime where heat accumulated after successive pulses, we observed the formation of polarization-controlled self-organized patterns expanding well beyond the focal volume, suggesting the presence of an evanescent coupling mechanism enhancing the self-orga-nization. In addition, our results, obtained with compositional elemental analysis coupled with Raman spectra suggest different ion migration mechanisms in the laser affected zone at the surface and inside the glass. The formation of crystalline tellurium (t-Te) from glass structural units due to photo-induced elemental dissociation was observed only at the surface. The formation of ultrathin layer of crystalline tellurium offers the possibility to explore structural transitions in two-dimensional (2D) glasses by observing changes in the short- and medium- range structural orders, induced by spatial confinement.2:50 PM(GOMD-186-2021) Sub-micrometric femtosecond laser structuring in silver-free and silver-containing gallo-germanate glassesR. Zaiter*1; T. Guerineau1; T. Cardinal1; Y. Petit2; B. Sapaly3; J. Harb2; L. Canioni2; M. Lancry31. Institut de Chimie de la Matière Condensée de Bordeaux (ICMCB) - Université de Bordeaux, Centre National de la Recherche Scientifique : UPR9048, France2. Centre d’Études Lasers Intenses et Applications (CELIA) – Centre National de la Recherche Scientifique : UMR5107, Commissariat à l’énergie atomique et aux énergies alternatives : DAM/CESTA, Université Sciences et Technologies - Bordeaux 1, France3. Institut de Chimie Moléculaire et des Matériaux d’Orsay (ICMMO) – Université Paris Saclay, FranceFemtosecond Direct Laser Writing technique (FDLW) has been widely used during the last two decades to perform 3D photo-struc-turing in glasses such as for PIC (Photonic Integrated circuits). The controlled formation of the photo-induced modifications allows developing remarkable optical properties such as birefrin-gence, photoluminescence, 2nd and 3rd harmonic generation. The understanding of correlations between the glass structure, the laser induced process and the resulting properties remains a tremendous challenge. To explore new opportunity in terms of applications and wavelength ranges, novel vitreous materials need to be explored. Among the different oxide glasses, heavy metal gallo-germanate oxide glasses have attracted attention and lead to a growing interest since they could combine local functionality, extended transparency window in the mid-IR up to 5.5 µm, chemical durability and robust mechanical properties. We report on the formation and structural evolution of embedded self-organized, polarization-dependent nanogratings in gallo-germanates induced by femtosecond laser pulses. Micro-Raman spectroscopy will be used for establishing local structure property relationship. Micro-fluorescence, micro-absorp-tion, phase-contrast imaging, and confocal fluorescence imaging of the FDLW structure will be discussed.Laser Interactions with Glass IIIRoom: Saturna IslandSession Chair: Theo Guerineau, University Laval3:30 PM(GOMD-187-2021) Formation of Nanoparticles in Glass Under Femtosecond Laser IrradiationC. Barker*1; S. McAnany2; K. J. Veenhuizen3; D. Nolan4; B. Aitken4; V. Dierolf1; H. Jain51. Lehigh University, Physics, USA2. Lehigh University, Materials Science & Engineering, USA3. Lebanon Valley College, Physics, USA4. Corning Incorporated, USA5. Lehigh University, International Materials Institute for New Functionality in Glass, USAFormation of metal nanoparticles (NP) such as of gold, copper and silver in silicate glass via dissolution of metal salt at high tempera-ture followed by precipitation at low temperature has been known to produce ruby color uniformly for millennia. This method exploits the strong temperature dependence of the solubility and stability of metal ions under near equilibrium conditions. By contrast, recently NPs have been produced in spatially selective regions deep inside the glass by fs laser irradiation under highly nonequilibrium condi-tions. We report on the formation of Ge NP in La2O3-B2O3-GeO2 glass by this method using Pharos 1026 nm wavelength laser focused 90 µm below the glass sample surface using a 50x, 0.6 NA objective lens with a pulse width of 175 fs, and a repetition rate of 200 kHz. It is shown that such NPs form only within a narrow range of pulse power of 2-3 µJ. Structural changes in the glass are characterized for various laser irradiation conditions by X-ray absorption near edge structure, Raman spectroscopy, and electron microscopy. Likely mechanisms for the formation of NPs in glass by fs laser irradiation will be presented.3:50 PM(GOMD-188-2021) Structure-Terahertz Properties-Ultrafast Laser Irradiation Correlations in Borosilicate, Tellurite, and Chalcogenide GlassesN. Tostanoski*1; S. K. Sundaram11. Alfred University, USAWe have studied Na2O WO3 TeO2, La2O3 WO3 TeO2, and Na2O B2O3 SiO2 borosilicate and tellurite glass systems, along with additional chalcogenide glass systems, with their chemistries systematically varied within the glass forming region, changing the glass struc-ture, which affects their terahertz properties. We prepared the glass samples via melting and casting, followed by annealing. The glasses were then characterized using differential scanning calorimetry (DSC), x-ray diffraction (XRD), ultraviolet-visible (UV-Vis), Fourier transformation infrared (FTIR), Raman spectroscopy, and time-do-main terahertz spectroscopy (THz-TDS). In addition, ultrafast laser pulses (e.g., ~ 40–100 femtoseconds) were used to irradiate these glass samples, modifying the local glass structure and their optical properties. Glass structural changes made via laser irradiation are correlated to terahertz properties of these glasses. Linear correla-tion between optical and THz refractive indices will be reported for the glass systems. Any deviation from linearity and its origin will be presented.

Investigating femtosecond laser interaction with tellurite glass family

PORTO@iris (Publications Open Repository TOrino - Politecnico di Torino)

18 October 2022POLITECNICO DI TORINORepository ISTITUZIONALEInvestigating femtosecond laser interaction with tellurite glass family / Torun, G.; Kishi, T.; Pugliese, D.; Milanese, D.;Descrovi, E.; Bellouard, Y.. - ELETTRONICO. - GOMD S3: Optical and Electronic Materials and Devices - Fundamentalsand Applications:(2021). ((Intervento presentato al convegno Glass & Optical Materials Division 2021 Annual Meeting(GOMD 2021) tenutosi a Online nel 13-16 Dicembre 2021.OriginalInvestigating femtosecond laser interaction with tellurite glass familyPublisher:PublishedDOI:Terms of use:openAccessPublisher copyright(Article begins on next page)This article is made available under terms and conditions as specified in the  corresponding bibliographic description inthe repositoryAvailability:This version is available at: 11583/2957338 since: 2022-03-04T12:52:14ZThe American Ceramic Society*Denotes Presenter 2021 PACRIM/GOMD Conference 173Abstracts2:30 PM(GOMD-185-2021) Investigating femtosecond laser interaction with tellurite glass familyG. Torun*1; T. Kishi3; D. Pugliese2; D. Milanese4; E. Descrovi2; Y. Bellouard11. EPFL, Switzerland2. Politecnico di Torino, Department of Applied Science and Technology and RU INSTM, Italy3. Tokyo Institute of Technology, Department of Chemistry and Materials Science, Japan4. Università di Parma, Department of Engineering and Architecture and RU INSTM, ItalyFocusing ultrafast laser pulses induce localized permanent structural modifications on the surface or in transparent materials, that are of particular interest for photonic applications. Among the materials of interest, the tellurite glass family is attractive for near-infrared and photonics applications due to its broad-transparency window and high optical nonlinearity. Here, we systematically investigate struc-tural changes occurring in various TeO2-based glasses exposed to femtosecond laser with various laser parameters. Remarkably, in a regime where heat accumulated after successive pulses, we observed the formation of polarization-controlled self-organized patterns expanding well beyond the focal volume, suggesting the presence of an evanescent coupling mechanism enhancing the self-orga-nization. In addition, our results, obtained with compositional elemental analysis coupled with Raman spectra suggest different ion migration mechanisms in the laser affected zone at the surface and inside the glass. The formation of crystalline tellurium (t-Te) from glass structural units due to photo-induced elemental dissociation was observed only at the surface. The formation of ultrathin layer of crystalline tellurium offers the possibility to explore structural transitions in two-dimensional (2D) glasses by observing changes in the short- and medium- range structural orders, induced by spatial confinement.2:50 PM(GOMD-186-2021) Sub-micrometric femtosecond laser structuring in silver-free and silver-containing gallo-germanate glassesR. Zaiter*1; T. Guerineau1; T. Cardinal1; Y. Petit2; B. Sapaly3; J. Harb2; L. Canioni2; M. Lancry31. Institut de Chimie de la Matière Condensée de Bordeaux (ICMCB) - Université de Bordeaux, Centre National de la Recherche Scientifique : UPR9048, France2. Centre d’Études Lasers Intenses et Applications (CELIA) – Centre National de la Recherche Scientifique : UMR5107, Commissariat à l’énergie atomique et aux énergies alternatives : DAM/CESTA, Université Sciences et Technologies - Bordeaux 1, France3. Institut de Chimie Moléculaire et des Matériaux d’Orsay (ICMMO) – Université Paris Saclay, FranceFemtosecond Direct Laser Writing technique (FDLW) has been widely used during the last two decades to perform 3D photo-struc-turing in glasses such as for PIC (Photonic Integrated circuits). The controlled formation of the photo-induced modifications allows developing remarkable optical properties such as birefrin-gence, photoluminescence, 2nd and 3rd harmonic generation. The understanding of correlations between the glass structure, the laser induced process and the resulting properties remains a tremendous challenge. To explore new opportunity in terms of applications and wavelength ranges, novel vitreous materials need to be explored. Among the different oxide glasses, heavy metal gallo-germanate oxide glasses have attracted attention and lead to a growing interest since they could combine local functionality, extended transparency window in the mid-IR up to 5.5 µm, chemical durability and robust mechanical properties. We report on the formation and structural evolution of embedded self-organized, polarization-dependent nanogratings in gallo-germanates induced by femtosecond laser pulses. Micro-Raman spectroscopy will be used for establishing local structure property relationship. Micro-fluorescence, micro-absorp-tion, phase-contrast imaging, and confocal fluorescence imaging of the FDLW structure will be discussed.Laser Interactions with Glass IIIRoom: Saturna IslandSession Chair: Theo Guerineau, University Laval3:30 PM(GOMD-187-2021) Formation of Nanoparticles in Glass Under Femtosecond Laser IrradiationC. Barker*1; S. McAnany2; K. J. Veenhuizen3; D. Nolan4; B. Aitken4; V. Dierolf1; H. Jain51. Lehigh University, Physics, USA2. Lehigh University, Materials Science & Engineering, USA3. Lebanon Valley College, Physics, USA4. Corning Incorporated, USA5. Lehigh University, International Materials Institute for New Functionality in Glass, USAFormation of metal nanoparticles (NP) such as of gold, copper and silver in silicate glass via dissolution of metal salt at high tempera-ture followed by precipitation at low temperature has been known to produce ruby color uniformly for millennia. This method exploits the strong temperature dependence of the solubility and stability of metal ions under near equilibrium conditions. By contrast, recently NPs have been produced in spatially selective regions deep inside the glass by fs laser irradiation under highly nonequilibrium condi-tions. We report on the formation of Ge NP in La2O3-B2O3-GeO2 glass by this method using Pharos 1026 nm wavelength laser focused 90 µm below the glass sample surface using a 50x, 0.6 NA objective lens with a pulse width of 175 fs, and a repetition rate of 200 kHz. It is shown that such NPs form only within a narrow range of pulse power of 2-3 µJ. Structural changes in the glass are characterized for various laser irradiation conditions by X-ray absorption near edge structure, Raman spectroscopy, and electron microscopy. Likely mechanisms for the formation of NPs in glass by fs laser irradiation will be presented.3:50 PM(GOMD-188-2021) Structure-Terahertz Properties-Ultrafast Laser Irradiation Correlations in Borosilicate, Tellurite, and Chalcogenide GlassesN. Tostanoski*1; S. K. Sundaram11. Alfred University, USAWe have studied Na2O WO3 TeO2, La2O3 WO3 TeO2, and Na2O B2O3 SiO2 borosilicate and tellurite glass systems, along with additional chalcogenide glass systems, with their chemistries systematically varied within the glass forming region, changing the glass struc-ture, which affects their terahertz properties. We prepared the glass samples via melting and casting, followed by annealing. The glasses were then characterized using differential scanning calorimetry (DSC), x-ray diffraction (XRD), ultraviolet-visible (UV-Vis), Fourier transformation infrared (FTIR), Raman spectroscopy, and time-do-main terahertz spectroscopy (THz-TDS). In addition, ultrafast laser pulses (e.g., ~ 40–100 femtoseconds) were used to irradiate these glass samples, modifying the local glass structure and their optical properties. Glass structural changes made via laser irradiation are correlated to terahertz properties of these glasses. Linear correla-tion between optical and THz refractive indices will be reported for the glass systems. Any deviation from linearity and its origin will be presented.

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Investigating femtosecond laser interaction with tellurite glass family

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