Excellent piezoelectric and electrical properties of lithium-doped ZnO nanowires for nanogenerator applications

• Well-aligned Li-doped ZnO nanowires were successfully grown by the hydrothermal method.
• Li-doped ZnO NWFET was p-type with a high carrier mobility of 14.59 cm2/V.s.
• Li-doped ZnO NWs exhibit much higher piezoelectric output current than pure ZnO NWs.
• Li-doped ZnO NW is a promising material for nanogenerator devices.

The well-aligned Li-doped zinc oxide nanowires (ZnO NWs) were successfully grown on Si substrates with seed layer by the hydrothermal method. The presence of Li in ZnO NWs is confirmed through EELS spectrum analysis. The acceptor energy level of the Li dopant is estimated to be 93.6 meV from the temperature-dependent PL spectra. From the SQUID measurements, the coercivity and saturation magnetization of the Li-doped ZnO NWs at room temperature are found to be 166 Oe and 9.64 memu/g, respectively. Additionally, the Li-doped ZnO NWFET confirms that the NWs were p-type with a high carrier mobility of 14.59 cm2/V s and an effective hole carrier concentration of 1.13×1017 cm−3. The piezoelectric response of the Li-doped ZnO NWs produces much higher piezoelectric output current, voltage, and power than pure ZnO NWs. These results indicated that p-type ZnO NWs are a promising candidate for nanogenerator devices.

TOC: Well-aligned Li-doped ZnO nanowires were successfully grown on Si substrates by the hydrothermal method, exhibiting superior physical properties. The ferromagnetic property makes Li-doped ZnO NWs a promising material in the field of DMSs. In addition, with high carrier mobility, output current, output voltage, and output power, Li-doped ZnO nanowires are of significant potential in applications for highly efficient nanogenerator devices.Figure optionsDownload as PowerPoint slide