(1) MV-indol can quantitatively detect viscosity with a high selectivity and a 75-fold enhancement in QY. (2) The mechanism for detection viscosity was confirmed by TD-DFT. (3) MV-indol can precisely localize in mitochondria and monitor the change of mitochondrial viscosity at the cellular level.

A 3D porous AgVO₃/BiVO₄@GA was fabricated by an in situ ion exchange method. In the as-prepared AgVO₃/BiVO₄@GA photocatalyst, GA with a 3D macrostructure, porous channels and excellent electrical conductivity can efficiently support AgVO₃ and facilitate cyclic regeneration, improve the mass transfer of reactants/products and promote the photogenerated charge separation rate in the photocatalytic process. Furthermore, benefitting from the ion exchange between Ag⁺ and Bi³⁺, the BiVO₄ can be well dispersed on AgVO₃, which avoids the agglomeration of AgVO₃ and BiVO₄ and further enhances the photocatalytic performance and cyclic stability of AgVO₃/BiVO₄@GA.

Our results indicate that the designed and reported molecules are superior to the Y3N molecule; thus, we recommend these molecules to experimentalists for future development of highly efficient solar cells.

A new red emission phosphor Ba₂Gd_0.67WO₆ was synthesized. The introduction of Mo extends the excitation peak from 370 to 425 nm, which is more suitable for solid-state lighting applications.