Size
and size distribution control along with the excitation/emission
wavelength manipulation are the most indispensable for both fundamental
research and applications of upconverting nanophosphors. In contradiction
to the usual Ostwald ripening
process, digestive ripening-mediated growth of core–shell nanostructures
is observed in a lanthanide-doped ternary fluoride system. Time-dependent
size evolution of NaYbF4:Tm@NaYF4 nanoparticles
is systematically investigated, and a K
sp-involved growth mechanism is proposed to better understand this
unusual phenomenon. The upconversion luminescence (UCL) intensity
and branch ratio of near-infrared to visible emission (NIR/VIS) dramatically
increase due to the NaYF4 coating but subsequently undergo
a decline when an additional SiO2 layer grows outside.
As a comparison, an alternant type of core–shell–shell
nanostructure, NaYbF4:Tm@SiO2@NaYF4, is further constructed, in which both the UCL intensity and NIR/VIS
ratio exhibit an inverse trend. The comparative analysis on the basis
of steady and transient spectroscopic data from NaYbF4:Tm,
and alternatively coated by silica and NaYF4 nanoshells,
respectively, demonstrates that the UCL properties can be regulated
through core–shell engineering once the optical behavior of
the surface states can be manipulated. The results provide a promising
alternative strategy to fabricate a uniform core–shell nanostructure
with multicompositions, and this NIRin–NIRout luminescent profile deserves an expectable vision for the subsequent
clinical applications of UCL imaging for deep biological tissues.
Na 3 V 2 (PO 4 ) 3 (NVP) has been regarded as a potential cathode material for sodium-ion batteries (SIBs) due to its excellent structural stability and rapid Na + conductivity. However, its electrochemical performances are restricted by the large bulk structure and poor electronic conductivity. The construction of porous NVP materials is a powerful method to improve the electrochemical properties. This concept aims to provide an overview of recent progress of porous NVP materials for SIBs. Herein, the synthetic strategies and formation mechanisms of porous NVP materials as well as the relationship between the porous structures and electrochemical performances of NVP materials are reviewed. Furthermore, the challenges and prospects for the preparation of porous NVP materials in this field are outlined.
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