Enhancing the temperature sensing property of a Ca _{0.79− x} Bi _x Er _0.01Yb _0.2MoO ₄ phosphor via local symmetry distortion and reduction in non-radiative channels

We demonstrate an enhancement in the upconversion (UC) emission and temperature sensing property of a CaMoO ₄:Er/Yb phosphor via distortion of the local symmetry environments and reduction in no-radiative channels. Bi ³⁺ ion co-doping creates a local distortion while the average tetragonal structure of CaMoO ₄ remains intact. This creates asymmetry around the Er ³⁺ ions which improves the UC emission. Furthermore, our calculations on XRD data show a reduction in the dislocation density and the micro-strain in the crystal with the introduction of Bi ³⁺, which also favours the enhancement of UC emission as it reduces the non-radiative channels. Furthermore, the effect of this enhancement on the temperature sensing property of Er ³⁺ ion has also been revealed. Our results show that the UC emission is enhanced about 25 times for Bi ³⁺ co-doped samples which improves the temperature sensitivity significantly. The samples, both with and without Bi ³⁺ co-doping, exhibited relative sensitivities of 0.0068 K ⁻¹ at 300 K and 0.0057 K ⁻¹ at 298 K which is a significant improvement and indicates the potential of the material for temperature sensing applications. This proof-of-concept provides a deeper understanding of the effect of Bi ³⁺ doping on UC emission and opens new avenues for the development of high-performance temperature sensing materials.

We demonstrate an enhancement in the upconversion (UC) emission and temperature sensing property of a CaMoO ₄:Er/Yb phosphor via distortion of the local symmetry environments.