Abstract:Since 2012, zinc gallogermanate has drawn interests as an excellent host phosphor for a variety of dopants (e.g., Cr3+, Bi3+ and Mn2+). However, the origin of its self‐activated luminescence has been largely unknown. Here, zinc gallogermanate of the composition Zn1+xGa2−2xGexO4 (0 ≤ x ≤ 1) is prepared by solid‐state reaction, and the evolution of the crystal structure with the composition is studied. The phosphors show a broad white‐bluish emission upon excitation by ultraviolet (UV) light, and the luminescenc… Show more
“…The compositional evolution of the XRD patterns accord with Allix's work on the same materials as those studied in this work [9]. A more detailed study on the structure of zinc gallogermanate phosphors can also be referred to our recent publication [11].…”
Section: Resultssupporting
confidence: 85%
“…It is found that Ga 2 O 3 and GeO 2 get evaporated slightly during the preparation course. Previous EPR study of the non-doped zinc gallogermanate indicates that the host matrix contains the gallium and germanium vacancies, which act as the emitting centers responsible for the self-luminescence of the nondoped phosphors [10,11]. XRD patterns of the samples are shown in Fig.…”
Nowadays, one-phase and full-color phosphors have gained increasing interest. Here, we show that Mn-activated zinc gallogermanate, Zn 1+x Ga 2-2x Ge x O 4 : Mn, x = 0 ~1, phosphors exhibit a broadly tunable luminescence from green to deep red with the substitution of Ga 3+ by Ge 4+ . The green and deep red emissions are attributed to Mn 2+ and Mn 4+ occupying the tetrahedrally coordinated Zn 2+ and octahedrally coordinated Ga 3+ sites, respectively. The origin of the tunable luminescence is discussed. The present phosphors have potential uses in field emission displays and in vivo bio-imaging. The in vivo activation of persistent nanophosphors for optical imaging of vascularization, tumours and grafted cells," Nat.
“…The compositional evolution of the XRD patterns accord with Allix's work on the same materials as those studied in this work [9]. A more detailed study on the structure of zinc gallogermanate phosphors can also be referred to our recent publication [11].…”
Section: Resultssupporting
confidence: 85%
“…It is found that Ga 2 O 3 and GeO 2 get evaporated slightly during the preparation course. Previous EPR study of the non-doped zinc gallogermanate indicates that the host matrix contains the gallium and germanium vacancies, which act as the emitting centers responsible for the self-luminescence of the nondoped phosphors [10,11]. XRD patterns of the samples are shown in Fig.…”
Nowadays, one-phase and full-color phosphors have gained increasing interest. Here, we show that Mn-activated zinc gallogermanate, Zn 1+x Ga 2-2x Ge x O 4 : Mn, x = 0 ~1, phosphors exhibit a broadly tunable luminescence from green to deep red with the substitution of Ga 3+ by Ge 4+ . The green and deep red emissions are attributed to Mn 2+ and Mn 4+ occupying the tetrahedrally coordinated Zn 2+ and octahedrally coordinated Ga 3+ sites, respectively. The origin of the tunable luminescence is discussed. The present phosphors have potential uses in field emission displays and in vivo bio-imaging. The in vivo activation of persistent nanophosphors for optical imaging of vascularization, tumours and grafted cells," Nat.
“…21 , it is very difficult to determine unambiguously the exact Zn 1+ x Ga 2−2 x Ge x O 4 phase in GCs, owing to the undistinguishable XRD patterns between the two end-members, ZnGa 2 O 4 ( x = 0) and Zn 2 GeO 4 ( x = 1). By comparing the Raman spectra of the crystallized glasses with the standard Zn 1+ x Ga 2−2 x Ge x O 4 polycrystals synthesized in our lab by solid-state reaction (for more detail, refer to our previous work 19 ), we provide the first direct evidence for the formation of Zn 1+ x Ga 2−2 x Ge x O 4 with x ≥ 0.4 in GCs (Fig. S1(b), supporting information).Figure 1( a ) XRD patterns of the as-made Ni 2+ doped glass (ZGO-0.15PG), crystallized glass (ZGO-0.15GC) and standard ZnGa 2 O 4 crystal (PDF card no.…”
Selective doping of Ni2+ in octahedral sites provided by nanocrystals embedded in glass-ceramics (GCs) is crucial to the enhancement of broadband near-infrared (NIR) emission. In this work, a NIR emission with a full-width-at-half-maximum (FWHM) of 288 nm is first reported from ZnGa2O4: Ni2+ nano-spinels embedded GCs with excellent transparency. A comparison is made of the NIR luminescence properties of Ni2+ doped GCs containing ZnGa2O4, germanium-substituted ZnGa2O4 nano-spinels (Zn1+xGa2−2xGexO4), and Zn2GeO4/Li2Ge4O9 composite nanocrystals that are free of Ga3+. The results show that ZnGa2O4: Ni2+ GCs exhibit a significantly enhanced NIR emission. The incorporation of the nucleating agent TiO2 is favored in terms of the increased luminescence intensity and prolonged lifetime. The possible causes for the enhancement effect are identified from the crystal structure/defects viewpoint. The newly developed GCs incorporate good reproducibility to allow for a tolerance of thermal treatment temperature and hence hold great potential of fiberization via the recently proposed “melt-in-tube” method. They can be considered as promising candidates for broadband fiber amplifiers.
“…Hence, in this work, a simple fluorescence probe method was chosen, to prove the existence of with its effect on LPL performance. At present, germanates have been developed as LPL phosphors due to their low synthesis temperature, high stability, and reasonable conductivity as an oxide host . In this work, Ca 2 Ga 2 GeO 7 (CGG) with self‐activated properties was chosen as the host matrix.…”
Acting as the electron trap, oxygen vacancies can strongly influence the long persistent luminescence (LPL) properties were verified in Ca2Ga2GeO7: Zn2+ (CGGZ) phosphor. The existence of oxygen vacancies in this self‐excitation material was confirmed by a simple fluorescence probe method. The introduction of zinc ions promotes the generation of oxygen vacancies, as well as optimizes its LPL properties. Thermoluminescence (TL) analysis revealed that electrons in deep trap will effectively transfer to the shallow one via the bridge of interstitial zinc. Accordingly, a mechanism for PL and LPL in this Gallogermanates was provided.
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