Your search keyword '"He, Xiaofeng"' showing total 3 results

1. Coordination-enhanced extraction of rare earth metals from waste polishing powder and facile preparation of a mesoporous Ce-La oxide.

Author

He, Xiaofeng, Chen, Lin, Chen, Peng, Liu, Weifeng, Zhang, Duchao, and Yang, Tianzu

Subjects

*RARE earth metals, *CERIUM oxides, *METAL wastes, *PRECIPITATION (Chemistry), *STABILITY constants

Abstract

[Display omitted] • An Efficient and value-added flowsheet for recycling rare earth polishing powder waste is proposed. • Coordination enhanced led to high leaching ratios in mild acidic conditions. • The coordination stability constant of Ce3+-ascorbic acid was determined. • High-purity mesoporous Ce-La oxide cube was synthesized by a facile chemical precipitation method. Efficient and environmental-friendly recycling of rare earth polishing powder waste (REPPW) is imperative not only to ecological well-being but also to sustainability of critical rare earth resources. However, the low leaching efficiency of rare earth elements in mild acidic conditions and complicated synthesis procedure of high-end products hindered industrial recycling of REPPW. Herein, an ascorbic acid-H 2 SO 4 system with mild conditions, i.e., ascorbic acid concentration = 0.042 mol/dm3, H 2 SO 4 concentration = 1 mol/dm3, liquid to solid ratio = 20 cm3/g and temperature = 353 K, is proposed for leaching REPPW, in which the leaching ratios of Ce and La reached 96.79 % and 93.81 %, respectively. The coordination stability constants of Ce3+-ascorbic acid, i.e., β 1 = 106.88 and β 2 = 1013.03, were determined by pH-potentiometry, which revealed that the enhanced Ce3+ dissolution in this mild leaching system was attributed to Ce3+-ascorbic acid coordination. Subsequently, a high-purity, mesoporous Ce-La oxide cube was synthesized from the leaching solution by a facile chemical precipitation method at atmospheric pressure and temperature. The product had a composition of 78.07 wt% CeO 2 and 21.93 wt% La 2 O 3 , and its average pore diameter was 7.30 nm. Its reducibility was 1.52 times higher than the theoretical value, suggesting a high potential for catalyzing redox reactions. This work proposes an efficient and value-added process for recycling REPPW, which helps to enlighten the sustainable utilization of secondary rare earth resources. [ABSTRACT FROM AUTHOR]

Published

2023

2. Lignocellulose nanofibril/gelatin/MXene composite aerogel with fire-warning properties for enhanced electromagnetic interference shielding performance.

Author

Li, Yuehu, Chen, Yian, He, Xiaofeng, Xiang, Zhouyang, Heinze, Thomas, and Qi, Haisong

Subjects

*FIREPROOFING agents, *ELECTROMAGNETIC interference, *ELECTROMAGNETIC shielding, *AEROGELS, *LIGNOCELLULOSE, *HEAT release rates, *GELATIN

Abstract

[Display omitted] • Phosphated lignocellulose nanofibrils were combined with MXene and gelatin; • The aerogel exhibited excellent fire retardancy with fire-warning performance; • Performance of electromagnetic interference shielding also achieved highly. Lightweight electromagnetic interference (EMI) shielding material with environment-friendly and high fire-safe has imperative practical significance in civil electronic devices. Herein, a distinct strategy was proposed to integrate phosphated lignocellulose nanofibrils (PLCNFs), gelatin, and MXene into a hybrid composite aerogel (PGM aerogel) with ultralight weight and high porosity. Due to the synergistic flame retardant effect of the ternary mixture, PGM aerogel exhibited excellent fire retardancy, whose dramatical changes in electronic resistance was supposed to achieve a short fire-warning signal (∼1 s). The limiting oxygen index (LOI) was as high as 32 % and the peak heat release rate (PHRR) was relatively as low as 30.1 W/g. Furthermore, the aerogel also displayed great specific EMI shielding effectiveness (SE) of SSE/t (14230 dB cm2 g−1) at 8.2 GHz. Therefore, this PGM aerogel can be a potential candidate in both EMI shielding and fire-warning fields. [ABSTRACT FROM AUTHOR]

Published

2022

3. Interface barrier strategy for perovskite solar cells realized by In-situ synthesized polyionic layer.

Author

Xu, Gaobo, Xu, Cunyun, Chen, Lijia, Ye, Jin, Dong, Jun, Zhong, Yuanxin, Li, Fuling, He, Xiaofeng, Yao, Yanqing, You, Jiayu, and Song, Qunliang

Subjects

*SOLAR cells, *PHASE transitions, *OPEN-circuit voltage, *INTERFACIAL stresses, *ELECTRON transport, *BAND gaps, *PEROVSKITE

Abstract

[Display omitted] • Observed the phase transition of perovskite driven by SnO 2 under UV light. • In-situ synthesis of PSS-Pb layer at the interface of SnO 2 /perovskite. • The PSS-Pb layer was used as barrier to inhibit phase-transition of perovskite. • The PSS-Pb layer stabilize the interface and passivate interface defects. • Obtained a high open-circuit voltage of 1.19 V and an improved efficiency of 22.26% The harmonious coordination between the perovskite and the charge transport layer is the prerequisite for the high efficiency and stability of perovskite solar cells (PSCs). The excellent photoelectric and solution processable SnO 2 electron transport material opens the most commercial potential of planar PSCs. However, SnO 2 has rich surface activity and photocatalytic properties, which will deteriorate perovskite after absorbing UV light and seriously affect the stability and efficiency of PSCs. Here, the interface barrier strategy is introduced to insert an anchored-then-rinsed lead polystyrene sulfonate (ARPSS-Pb) polyionic layer between SnO 2 and perovskite via in-situ synthesis method to construct a new stable interface, which can effectively block the phase transition of perovskite driven by photocatalytic SnO 2. In addition, ARPSS-Pb also has the functions of passivating interfacial defects, relaxing interfacial stress and guiding crystallization of perovskite. PSCs based on ARPSS-Pb achieved a power conversion efficiency (PCE) of 22.26%, much higher than 19.60% of the control devices. More importantly, after 1000 h of storage under continuous humidity conditions, up to 96.32% of the initial PCE is maintained. A high open circuit voltage (V OC) as high as 1.190 V has been obtained for ARPSS-Pb based devices. To our best knowledge, this is the highest V OC achieved in the system of perovskite with 1.56 eV energy gap. [ABSTRACT FROM AUTHOR]

Published

2022