The exploration of highly efficient nonprecious metal bifunctional electrocatalysts to boost oxygen evolution reaction and oxygen reduction reaction is critical for development of high energy density metal-air batteries. Herein, a class of CuS/NiS 2 interface nanocrystals (INs) catalysts with atomic-level coupled nanointerface, subtle lattice distortion, and plentiful vacancy defects is reported. The results from temperature-dependent in situ synchrotron-based X-ray absorption fine spectroscopy and electron spin resonance spectroscopy demonstrate that the lattice distortion of 14.7% in CuS/NiS 2 caused by the strong Jahn-Teller effect of Cu, the strong atomic-level coupled interface of CuS and NiS 2 domains, and distinct vacancy defects can provide numerous effective active sites for their excellent bifunctional performance. A liquid Zn-air battery with the CuS/NiS 2 INs as air electrode displays a large peak power density (172.4 mW cm −2 ), a high specific capacity (775 mAh g Zn −1 ), and long cycle life (up to 83 h), making the CuS/NiS 2 INs among the best bifunctional catalysts for Zn-air battery. More remarkably, the flexible CuS/NiS 2 INsbased solid-state Zn-air batteries can power the LED after twisting, making them be promising in portable and wearable electronic devices.
A delivery system for bioactive conjugated linoleic acid (CLA) through a self-assembled amylose-CLA complex was investigated in comparison with a beta-cyclodextrin (BCD)-CLA complex. Successful complexation between CLA and amylose or BCD was confirmed by differential scanning calorimetry, X-ray diffraction, and Fourier transform infrared spectral analysis. The yield and complexing percentages were 71.9 and 1.4% for the amylose-CLA complex and 42.3 and 7.7% for the BCD-CLA complex, respectively. However, the amylose-CLA complex showed a better antioxidative protection effect on CLA than BCD-CLA complex, supporting a strong complexing interaction between CLA and amylose shown by thermogravimetric analysis. Compared to 15.9% of CLA released from the BCD-CLA complex under simulated small intestine conditions, 95.6% of CLA was released from the amylose-CLA complex. These results indicate that an amylose-lipid complex self-assembled in the natural way of food component interaction can be used to protect and deliver functional lipids or other bioactive components into the targeted small intestine for absorption.
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