The underlying mechanism shows that the LUE of the PbTe/Pb-based nanocomposite had an obvious increase compared to that of the individual PbTe/Pb nanomaterial. Figure 6 The photoelectric mechanism schematic diagram. (a) The carrier generation mechanism schematic diagram in the PbTe/Pb nanostructure under light irradiation. (b) The carrier generation mechanism schematic diagram in the PbTe/Pb-based nanocomposite find more under light irradiation.

Conclusions In summary, the PbTe/Pb-based nanocomposite is assembled by combining the PbTe/Pb nanostructure arrays and the Zn x Mn1−x S nanoparticles. The photoelectric measurement shows that the photoelectric performance of the PbTe/Pb-based nanocomposite had an obvious improvement SIS3 research buy compared to that of the individual PbTe/Pb nanomaterial. The improvement of photoelectric performance could originate from the synergistic effect of the incident light of the laser and the stimulated radiation of the Zn x Mn1−x S nanoparticles on the surface of the PbTe/Pb nanostructure. The result implies that the underlying mechanism may be used to improve the performance of nano-optoelectronic devices and explore the novel properties of nanocomposites. Acknowledgments This work is supported by the National Science Foundation of China (no.11204271, 11104248), Scientific Research Fund

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