posted on 2018-08-01, 00:00authored byBin Xue, Dan Wang, Langping Tu, Dapeng Sun, Pengtao Jing, Yulei Chang, Youlin Zhang, Xiaomin Liu, Jing Zuo, Jun Song, Junle Qu, Evert Jan Meijer, Hong Zhang, Xianggui Kong
Dye sensitization
is becoming a new dimension to highly improve
the upconversion luminescence (UCL) of lanthanide-doped upconversion
nanoparticles (UCNPs). However, there is still a lack of general understanding
of the dye–UCNPs interactions, especially the confused large
mismatch between the inputs and outputs. By taking dye-sensitized
NaYF4:Yb/Er@NaYF4:Nd UCNPs as a model system,
we not only revealed the in-depth energy-dissipative process for dye-sensitized
UCL but also confirmed the first ever experimental observation of
the energy back transfer (EBT) in the dye-sensitized UCL. Furthermore,
this energy-dissipative EBT restricted the optimal ratio of dyes to
UCNP. By unearthing all of the energy loss behind the EBT, energy
transfer, and energy migration processes, this paper sheds light on
the further design of effective dye-sensitized nanosystems for UCL
or even downconversion luminescence.