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Piezoelectric properties of a near strain-free lead zirconate titanate thin films deposited on a Si substrate
摘要: Chemical solution deposition (CSD)-derived near strain-free lead zirconate titanate (PZT) thin films on a Si substrate were prepared by designing a buffer layer structure. Strain-free PZT thin films with different compositions ranging from Zr/Ti = 50/50 to 58/42 were obtained to demonstrate lattice strain effects on piezoelectric properties. Results show that a near strain-free condition was attained with a SrRuO3 (SRO: 160 nm)/(La0.5,Sr0.5)CoO3 (LSCO: 90 nm)/LaNiO3 (LNO: 120 nm)/stacking structure, even on a Si substrate. The highest effective d33 value of the near strain-free PZT thin film was observed at 53/47 composition, which is the same as bulk materials, although the highest effective d33 value was obtained from 58/42 composition under the compressive lattice strain condition.
关键词: Chemical solution deposition,Piezoelectricity,Thin films,Multilayer structure,Lattice strain,Sol-gel preparation
更新于2025-09-23 15:22:29
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Na incorporation controlled single phase kesterite Cu2ZnSnS4 solar cell material
摘要: It is theoretically and experimentally challenging to fabricate single phase Cu2ZnSnS4 (CZTS) and more difficult to synthesize it by sol-gel method. Theoretical work reveals that Na can passivate the dangling bonds in the grain boundaries of CZTS and thus enhance the photovoltaic performance. Therefore, Na incorporation may be an effective way in passivating defects in CZTS films and fabricating CZTS with high quality and single phase. In this study, we will try to incorporate Na into CZTS films by sol-gel method to help passivate defects in CZTS and achieve single phase kesterite CZTS films using a different solvent 2-methoxybutanol. Different Na/(Cu+Zn+Sn) atomic ratios (0%-3%) will be employed. Through controlling Na incorporation amount in solution, we can prevent the generation of other phases like SnO2 and a pure single phase kesterite CZTS can be achieved. The optical band gap of the optimal CZTS film is 1.24 eV. All Na doped CZTS films show p-type conduction behavior.
关键词: Solar energy materials,Sol-gel preparation,Crystal structure
更新于2025-09-19 17:13:59
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Investigations on photovoltaic performance of sol–gel derived BiFeO3-based heterostructures via compositional modification
摘要: In this paper, sol–gel is used to synthesize BiFeO3 (BFO), RGO/BFO, RGO/BFO/TiO2, TiCl4-modi?ed RGO/BFO/TiO2 and MAPI/RGO/BFO/TiO2 thin ?lms onto Pt/Ti/SiO2/Si substrate. RGO/BFO/TiO2 thin ?lm possesses high power conversion ef?ciency (g) of 3.11% and ?ll factor (FF) of 0.72, owing to the favorable effects of TiO2 and RGO on promoting electron transfer and electron injection, respectively. All the results indicate that BFO-based heterostructure thin ?lm is a promising candidate for designing solar energy devices.
关键词: Thin ?lms,Sol-gel preparation,Electrical properties
更新于2025-09-11 14:15:04
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Nanostructured Titania Templated by Natural Cellulose Substance: Effect of Vanadium-Doping on the Anatase-to-Rutile Phase Transformation
摘要: Vanadium-doped rutile titania nanomaterial was synthesized by calcination of titania/vanadia composite thin gel films pre-coated natural cellulose substance (e.g., ordinary filter paper) at a relatively low temperature (600 °C). A better mixture of titanium and vanadium species is achieved during the layer-by-layer (LbL) deposition process with cellulose nanofiber as a template, leading to more vanadium dopants incorporated in the titania crystal lattices. By sufficient vanadium-doping, the phase transformation temperature from anatase to rutile phase of titania is decreased effectively. The doping mode and existing state of vanadium in the titania nanomaterials and the effect on the anatase-to-rutile phase transformation have been studied. This strategy provides a facile and effective route to facilitate the phase transformation of various nanostructured metal oxides templated by natural cellulose substance through doping appropriate functional metal ions in the LbL deposition process.
关键词: Biomimetic,Ceramics,Sol–Gel Preparation,Phase Transformation,Titania
更新于2025-09-04 15:30:14