Abstract
Biomedical imaging and labeling through luminescence microscopy requires materials that are active in the near-infrared spectral range, i.e., within the transparency window of biological tissue. For this purpose, tailoring of Mn(2+)-Mn(2+) activator aggregation is demonstrated within the ABF(3) fluoride perovskites. Such tailoring promotes distinct near-infrared photoluminescence through antiferromagnetic super-exchange across effective dimers. The crossover dopant concentrations for the occurrence of Mn(2+) interaction within the first and second coordination shells comply well with experimental observations of concentration quenching of photoluminescence from isolated Mn(2+) and from Mn(2+)-Mn(2+) effective dimers, respectively. Tailoring of this procedure is achieved via adjusting the Mn-F-Mn angle and the Mn-F distance through substitution of the A(+) and/or the B(2+) species in the ABF(3) compound. Computational simulation and X-ray absorption spectroscopy are employed to confirm this. The principle is applied to produce pure anti-Stokes near-infrared emission within the spectral range of ≈760-830 nm from codoped ABF(3):Yb(3+),Mn(2+) upon excitation with a 976 nm laser diode, challenging the classical viewpoint where Mn(2+) is used only for visible photoluminescence: in the present case, intense and tunable near-infrared emission is generated. This approach is highly promising for future applications in biomedical imaging and labeling.