Anomalous variation of electrical transport property and amorphization in dense Alq<sub>3</sub>

Ke, Feng; Wang, Qinglin; Zhang, Junkai; Guo, Ying; Li, Yan; Liu, Cailong; Han, Yonghao; Ma, Yanzhang; Chen, Xiao‐Jia; Chen, Bin; Chen, Gao

doi:10.1039/c5ra01198a

Cited by 2 publications

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“…Since 2010, Wu et al have reported that stress-induced silver nanoparticles turn into one-dimensional (1D)-nanostructure arrays, [10] a pressure-driven sintering of spherical nanoparticle arrays into nanostructured gold architectures, [11] and a pressureinduced silver nanoparticle super-lattice into mechanically stable nanowires. [12] Since 2012, the pressure-induced surface nanocrystallizations in Cu 2 O, [13] Alq 3 , [14] and Zn 2 SnO 4 have been reported. [15] All the reported results in these two groups indicate that the pressure-induced physical interfaces affect the mechanical, optical, and electrical transportation properties, the phase sequence, transition pressure, etc.…”

Section: Introductionmentioning

confidence: 99%

Effects of grinding-induced grain boundary and interfaces on electrical transportation and structure phase transition in ZnSe under high pressure

et al. 2016

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Interface and scale effects are the two most important factors which strongly affect the structure and the properties of nano-/micro-crystals under pressure. We conduct an experiment under high pressure in situ alternating current impedance to elucidate the effects of interface on the structure and electrical transport behavior of two ZnSe samples with different sizes obtained by physical grinding. The results show that (i) two different-sized ZnSe samples undergo the same phase transitions from zinc blend to cinnabar-type phase and then to rock salt phase; (ii) the structural transition pressure of the 859-nm ZnSe sample is higher than that of the sample of 478 nm, which indicates the strong scale effect. The pressure induced boundary resistance change is obtained by fitting the impedance spectrum, which shows that the boundary conduction dominates the electrical transport behavior of ZnSe in the whole experimental pressure range. By comparing the impedance spectra of two different-sized ZnSe samples at high pressure, we find that the resistance of the 478-nm ZnSe sample is lower than that of the 859-nm sample, which illustrates that the sample with smaller particle size has more defects which are due to physical grinding.

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Section: Introductionmentioning

confidence: 99%

Effects of grinding-induced grain boundary and interfaces on electrical transportation and structure phase transition in ZnSe under high pressure

et al. 2016

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Visible light response, electrical transport, and amorphization in compressed organolead iodine perovskites

et al. 2016

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Recent scientific advances on organic-inorganic hybrid perovskites are mainly focused on the improvement of power conversion efficiency. So far, how compression tunes their electronic and structural properties remains less understood. By combining in situ photocurrent, impedance spectroscopy, and X-ray diffraction (XRD) measurements, we have studied the electrical transport and structural properties of compressed CH3NH3PbI3 (MAPbI3) nanorods. The visible light response of MAPbI3 remains robust below 3 GPa while it is suppressed when it becomes amorphous. Pressure-induced electrical transport properties of MAPbI3 including resistance, relaxation frequency, and relative permittivity have been investigated under pressure up to 8.5 GPa by in situ impedance spectroscopy measurements. These results indicate that the discontinuous changes of these physical parameters occur around the structural phase transition pressure. The XRD studies of MAPbI3 under high pressure up to 20.9 GPa show that a phase transformation below 0.7 GPa, could be attributed to the tilting and distortion of PbI6 octahedra. And pressure-induced amorphization is reversible at a low density amorphous state but irreversible at a relatively higher density state. Furthermore, the MAPbI3 nanorods crush into nanopieces around 0.9 GPa which helps us to explain why the mixed phase of tetragonal and orthorhombic was observed at 0.5 GPa. The pressure modulated changes of electrical transport and visible light response properties open up a new approach for exploring CH3NH3PbI3-based photo-electronic applications.

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Anomalous variation of electrical transport property and amorphization in dense Alq₃

Abstract: The experimental results indicate that the Al–oxine interaction can also be believed to be significant for the electrical transport properties of dense Alq3.

Cited by 2 publications

References 42 publications

Effects of grinding-induced grain boundary and interfaces on electrical transportation and structure phase transition in ZnSe under high pressure

Effects of grinding-induced grain boundary and interfaces on electrical transportation and structure phase transition in ZnSe under high pressure

Visible light response, electrical transport, and amorphization in compressed organolead iodine perovskites

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Anomalous variation of electrical transport property and amorphization in dense Alq3

Abstract: The experimental results indicate that the Al–oxine interaction can also be believed to be significant for the electrical transport properties of dense Alq3.

Cited by 2 publications

References 42 publications

Effects of grinding-induced grain boundary and interfaces on electrical transportation and structure phase transition in ZnSe under high pressure

Effects of grinding-induced grain boundary and interfaces on electrical transportation and structure phase transition in ZnSe under high pressure

Visible light response, electrical transport, and amorphization in compressed organolead iodine perovskites

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Anomalous variation of electrical transport property and amorphization in dense Alq₃