Issue 44, 2017

Design of Yb3+ optical bandwidths by crystallographic modification of disordered calcium niobium gallium laser garnets

Abstract

{Ca□}3[Nb1−xGax□]2(Ga1−yNby□)3O12-type cubic Ia[3 with combining macron]d garnets (CNGG) have been grown by the Czochralski method, either unmodified or incorporating different crystalline modifiers (Li+ or Mg2+), and Yb3+ as a laser dopant. From nuclear magnetic resonance, single crystal X-ray and powder neutron diffraction studies it is shown that Li+ incorporates exclusively into the 24d tetrahedral site of the host, removing tetrahedral-sited Nb5+ and filling cationic vacancies in this site. A comparison of low temperature (6 K) Yb3+ spectroscopy in crystals with different compositions at the tetrahedral sites and a modeling of energy positions of the 2F7/2(0) and 2F5/2(0′) Yb3+ levels show that the strongest contribution to the Yb3+ optical absorption/emission bandwidth is associated with the electric charge of cations/vacancies occupying the two tetrahedra at the shortest distance (3.12 Å) from the central 24c dodecahedral Yb3+. Cationic disorder over the remaining four tetrahedral, octahedral and dodecahedral sites also contributes to the Yb3+ bandwidth but to a lesser extent. To obtain the largest Yb3+ bandwidth, the two nearest tetrahedra must contain cations/vacancies with electric charges as different as possible. Although the decrease in the concentration of vacancies at tetrahedral sites associated with Li+ incorporation induces some reduction of the Yb3+ optical bandwidth with regard to the unmodified Yb:CNGG crystal, Li+ incorporation along with the use of high purity precursors yields crystals with less coloration, longer Yb3+ lifetime, and slightly larger thermal conductivity, which favors laser operation performance.

Graphical abstract: Design of Yb3+ optical bandwidths by crystallographic modification of disordered calcium niobium gallium laser garnets

Supplementary files

Article information

Article type
Paper
Submitted
20 Jun 2017
Accepted
13 Oct 2017
First published
16 Oct 2017

J. Mater. Chem. C, 2017,5, 11481-11495

Design of Yb3+ optical bandwidths by crystallographic modification of disordered calcium niobium gallium laser garnets

M. D. Serrano, J. O. Álvarez-Pérez, C. Zaldo, J. Sanz, I. Sobrados, J. A. Alonso, C. Cascales, M. T. Fernández-Díaz and A. Jezowski, J. Mater. Chem. C, 2017, 5, 11481 DOI: 10.1039/C7TC02760E

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