The local environment of Dy3+in selenium-rich chalcogenide glasses

Barney, Emma R.; Tang, Zhuoqi; Seddon, Angela; Furniss, David; Sujecki, S.; Benson, Trevor M.; Neate, Nigel; Gianolio, Diego

doi:10.1039/C4RA07192A

All Outputs (5)

Comparative study of praseodymium additives in active selenide chalcogenide optical fibers (2018)
Journal Article
Tang, Z., Sojka, L., Furniss, D., Nunes, J., Sakr, H., Barney, E., …Seddon, A. B. (2018). Comparative study of praseodymium additives in active selenide chalcogenide optical fibers. Optical Materials Express, 8(12), 3910-3926. https://doi.org/10.1364/OME.8.003910

The choice of rare earth additive when doping chalcogenide glasses can affect their mid-infrared fiber performance. Three praseodymium additives, Pr-foil, PrCl3 and PrI3 are investigated in Ge-As-Ga-Se fibers. All the fibers are X-ray amorphous and t... Read More about Comparative study of praseodymium additives in active selenide chalcogenide optical fibers.

Prospective on using mid-infrared supercontinuum laser sources for in vivo spectral discrimination of disease (2018)
Journal Article
Seddon, A. B., Napier, B., Lindsay, I., Lamrini, S., Moselund, P. M., Stone, N., …Farries, M. (2018). Prospective on using mid-infrared supercontinuum laser sources for in vivo spectral discrimination of disease. Analyst, 143(24), 5874-5887. https://doi.org/10.1039/c8an01396a

Mid-infrared (MIR) fibre-optics may play a future role in in vivo diagnosis of disease, including cancer. Recently, we reported for the first time an optical fibre based broadband supercontinuum (SC) laser source spanning 1.3 to 13.4 μm wavelength to... Read More about Prospective on using mid-infrared supercontinuum laser sources for in vivo spectral discrimination of disease.

Toward Mid-Infrared, Subdiffraction, Spectral-Mapping of Human Cells and Tissue: SNIM (Scanning Near-Field Infrared Microscopy) Tip Fabrication (2015)
Journal Article
Neate, N., Fay, M., Parmenter, C., Athanasiou, G. S., Ernst, J., Furniss, D., …Seddon, A. B. (2016). Toward Mid-Infrared, Subdiffraction, Spectral-Mapping of Human Cells and Tissue: SNIM (Scanning Near-Field Infrared Microscopy) Tip Fabrication. Journal of Lightwave Technology, 34(4), 1212-1219. https://doi.org/10.1109/JLT.2015.2496786

Scanning near-field infrared microscopy (SNIM) potentially enables subdiffraction, broadband mid-infrared (MIR:3–25-μm wavelength range) spectral-mapping of human cells and tissue for real-time molecular sensing, with prospective use in disease diagn... Read More about Toward Mid-Infrared, Subdiffraction, Spectral-Mapping of Human Cells and Tissue: SNIM (Scanning Near-Field Infrared Microscopy) Tip Fabrication.

Predictive, Miniature Co-Extrusion of Multilayered Glass Fiber-Optic Preforms (2015)
Journal Article
Bhowmick, K., Furniss, D., Morvan, H. P., Seddon, A. B., & Benson, T. M. (2016). Predictive, Miniature Co-Extrusion of Multilayered Glass Fiber-Optic Preforms. Journal of the American Ceramic Society, 99(1), 106-114. https://doi.org/10.1111/jace.13937

A miniature co-extrusion technique, to produce a concentric multilayered glass fiber-optic preform of ~3 mm diameter, is modeled and experimentally demonstrated. A three-dimensional, incompressible, noncavitating, and nonisothermal Computational Flui... Read More about Predictive, Miniature Co-Extrusion of Multilayered Glass Fiber-Optic Preforms.

The local environment of Dy3+in selenium-rich chalcogenide glasses (2014)
Journal Article
Barney, E. R., Tang, Z., Seddon, A., Furniss, D., Sujecki, S., Benson, T. M., …Gianolio, D. (in press). The local environment of Dy3+in selenium-rich chalcogenide glasses. RSC Advances, 4(80), https://doi.org/10.1039/C4RA07192A

The environment of Dy3+ is investigated when it is added as DyCl3 or Dy foil into two base glasses, Ge16.5As19−xGaxSe64.5, where x = 3 or 10 at%, at doping levels between 0 and 3000 parts per million by weight (ppmw) Dy3+. Extended X-ray Absorption F... Read More about The local environment of Dy3+in selenium-rich chalcogenide glasses.