Enhanced energy transfer in heterogeneous nanocrystals for near infrared upconversion photocurrent generation
journal contribution
posted on 2024-11-16, 05:54authored byLiang Wang, Long Ren, David Mitchell, Gilberto Casillas-Garcia, Wei Ren, C Ma, Xiaoxue Xu, Shihui Wen, F Wang, J Zhou, Xun XuXun Xu, Weichang Hao, Shi DouShi Dou, Yi Du
The key to produce inorganic heterogeneous nanostructures, and to integrate multiple functionalities, is to enhance or at least retain the functionalities of different components of materials. However, this ideal scenario is often deteriorated at the interface of the heterogeneous nanostructures due to lattice mismatches, resulting in downgraded performance in most hybrid nanomaterials. Here, we report that there is a narrow window in controlling temperature in a Lewis acid-base reaction process to facilitate epitaxial alignment during the synthesis of hybrid nanomaterials. We demonstrate a perfectly fused NaYF 4 :Yb,Tm@ZnO heterogeneous nanostructure, in which the semiconductor ZnO shell can be epitaxially grown onto lanthanide-doped upconversion nanoparticles. By achieving a matched crystal lattice, the interface defects and crystalline grain boundaries are minimized to enable more efficient energy transfer from the upconversion nanoparticles to the semiconductor, resulting in both enhanced upconversion luminescence intensity and superior photoelectrochemical properties. This strategy provides an outstanding approach to endow lanthanide-doped upconversion nanoparticles with versatile properties.
Funding
Multifunctional 2D materials for sustainable energy applications
Wang, L., Ren, L., Mitchell, D., Casillas-Garcia, G., Ren, W., Ma, C., Xu, X. X., Wen, S., Wang, F., Zhou, J., Xu, X., Hao, W., Dou, S. X. & Du, Y. (2017). Enhanced energy transfer in heterogeneous nanocrystals for near infrared upconversion photocurrent generation. Nanoscale, 9 (47), 18661-18667.