Your search keyword '"Wu, Hong"' showing total 28 results

1. Substantially enhancing enzymatic regioselective acylation of 1-β-d-arabinofuranosylcytosine with vinyl caprylate by using a co-solvent mixture of hexane and pyridine

Author

Zong, Min-Hua, Wu, Hong, and Tan, Zi-yang

Subjects

*ACYLATION, *PYRIMIDINES, *SOLVENTS, *CHEMICAL reactions, *NUCLEOSIDES, *HEXANE, *PYRIDINE

Abstract

Abstract: Novozym 435-catalyzed regioselective acylation of 1-β-d-arabinofuranosylcytosine (ara-C) with vinyl caprylate for the preparation of its 5′-O-acyl derivative has been performed in six co-solvent mixtures and three pure polar solvents for the first time. Novozym 435 displayed low activity towards 1-β-d-arabinofuranosylcytosine in pure polar solvents, although those solvents can dissolve the nucleosides well. When a hexane–pyridine co-solvent system was adopted, both the initial rate and the substrate conversion were enhanced markedly. The most suitable co-solvent, initial water activity, reaction temperature and the molar ratio of vinyl caprylate to ara-C were hexane/pyridine (28/72, v/v), 0.03, 40°C and 15, respectively. Under these conditions, the initial rate, the substrate conversion and the regioselectivity were as high as 99.0mmolh−1, 98% and >99%, respectively. The product of the Novozym 435-catalyzed reaction was characterized by 13C NMR and confirmed to be 5′-O-octanoyl 1-β-d-arabinofuranosylcytosine. [Copyright &y& Elsevier]

Published

2008

2. Robust and highly proton conductive COF composite membranes for fuel cell and electrochemical hydrogen compression.

Author

Gao, Zhong, Yin, Zhuoyu, Kong, Yan, Zhang, Leilang, Xing, Na, Zhu, Shiyi, Yao, Zengguang, Liu, Ziwen, Pang, Xiao, Wu, Hong, and Jiang, Zhongyi

Subjects

*FUEL cells, *TANNINS, *COMPOSITE membranes (Chemistry), *PROTONS, *PROTON conductivity, *ELECTRIC batteries, *TENSILE strength

Abstract

[Display omitted] • A hydrogen-bond binding strategy is proposed to fabricate iCOF nanosheets (iCONs) and tannic acid (TA) composite membranes. • TA nanoaggregates were synthesized as hydrogen-bond binders. • Abundant hydrogen-bond interactions enable flexible connection between iCONs. • Highly interconnected hydrogen-bond networks facilitate rapid proton transport. • The membranes showed both enhanced mechanical properties and proton conductivity. Robust and highly conductive proton exchange membrane (PEM) is the unremitting pursuit of numerous electrochemical energy technologies such as fuel cell and the emerging electrochemical hydrogen compression. Ionic covalent organic framework nanosheets (iCONs) with long-range ordered nanochannels and abundant ionic groups show substantial potential as next-generation PEM materials. However, it is challenging to assemble iCONs into membranes with both robustness and flexibility due to the electrostatic repulsion and rigid framework. Herein, we propose a hydrogen-bond binding strategy to fabricate sulfonic iCON (SCON) composite membranes by co-assembling tannic acid (TA) nanoaggregates and SCONs. The abundant and dynamically reversible hydrogen-bond interactions introduced by TA nanoaggregates establish effective linkage between SCONs and allow some restricted movements, endowing membranes with remarkably improved mechanical properties. The stacked SCONs construct long-range ordered nanochannels with well-arranged sulfonic groups in membranes, and the hydrogen-bond networks further facilitate the proton transport through Grotthuss mechanism. Consequently, TA/SCON composite membranes displays significantly enhanced tensile strength of 101.9 MPa, good flexibility and high proton conductivity of 490.1 mS cm−1 at 80 °C and 100 % RH simultaneously. This hydrogen-bond binding strategy offers a promising approach to fabricate robust and highly conductive PEMs for various proton-conducting applications. [ABSTRACT FROM AUTHOR]

Published

2024

3. In-situ exfoliation and dispersion of graphite via forced flow processing of highly elastic amorphous polylactide.

Author

Ji, Yuan, Song, Xudong, Wu, Ruixue, Wu, Hong, Guo, Shaoyun, and Qiu, Jianhui

Subjects

*POLYLACTIC acid, *SHEARING force, *STRAINS & stresses (Mechanics), *ELECTRIC conductivity, *NANOPARTICLES, *PYROLYTIC graphite, *GRAPHITE

Abstract

[Display omitted] • Forced flow processing for in-situ exfoliation and dispersion of Gt is proposed. • Backflow and extremely strong shear stress lead to the interlayer loosening of Gt. • 70 wt% of Gt in aPLA can be fully converted into uniformly dispersed GNPs. Graphene has received extensive attention from the industry due to its extraordinary physical and chemical properties. However, the development of low-cost, large-scale methods to prepare graphene and its derivatives via graphite (Gt) exfoliation is still a challenge. Herein, we propose a novel method to in-situ exfoliate and disperse Gt without any post-processing via exploiting the strong shear stress and irreducible deformation generated by the forced flow processing of highly elastic amorphous polylactide (aPLA). It is amazing that, after 8 times forced flow processing within 10 min, 70 wt% of Gt in aPLA is fully converted into uniformly dispersed graphite nanoplatelets (GNPs) with average lateral sizes of 2.28 μm and thicknesses of 8.82 nm. Mechanism analysis reveals that the combination of backflow with subsequent extremely strong shear stress results in the interlayer loosening of graphite toward continuous production of GNPs. The GNPs exhibit exceptional enhancements in the thermal and electrical conductivity of the composites. This ultra-efficient, extremely simple and solvent-free method can be scalable for industrial use. [ABSTRACT FROM AUTHOR]

Published

2024

4. Electrochemical hydrogen Compression: Module design and membrane development.

Author

Gao, Zhong, Fan, Chunyang, Yin, Zhuoyu, Wang, Sijia, Zhang, Leilang, Xing, Na, Zhu, Shiyi, Yao, Zengguang, Wu, Hong, and Jiang, Zhongyi

Subjects

*HYDROGEN, *ELECTRODE reactions, *OXIDE ceramics, *CHEMICAL structure, *ION-permeable membranes

Abstract

[Display omitted] • 1. Electrochemical hydrogen compression (EHC) can purify and compress hydrogen in one step. • 2. Working principle and module design of EHC are described and summarized. • 3. Developments of advanced proton-conducting membranes for EHC are reviewed. • 4. Challenges, future trends and prospects of EHC are discussed. Electrochemical hydrogen compression (EHC), which can purify and compress hydrogen in one step, has aroused broad interests due to its high efficiency, compact equipment, and quiet operation. Since the concept of EHC was proposed, considerable efforts have been devoted to this field. In this review, several aspects of EHC are comprehensively discussed. Firstly, the working principle of EHC is presented with a focus on the electrode reactions, overpotentials, and performance indicators. Subsequently, the major functions, required properties, common materials and recent progress on the design and development of EHC modules are overviewed. As the key part of EHC, recent advances in proton-conducting membranes are particularly summarized, including polymeric proton exchange membranes, mixed matrix proton exchange membranes, and proton ceramic oxide membranes. The focus is on the chemical structures, proton transfer mechanisms, factors affecting performances, and applications for hydrogen purification and compression. Finally, the challenges, future trends, and prospects associated with each module of EHC are discussed. [ABSTRACT FROM AUTHOR]

Published

2024

5. Biomimetic construction of smart nanochannels in covalent organic framework membranes for efficient ion separation.

Author

Ren, Liang, Chen, Jianxin, Han, Jian, Liang, Jinsheng, and Wu, Hong

Subjects

*SOLUTION (Chemistry), *AZOBENZENE derivatives, *BIOLOGICAL membranes, *POTASSIUM channels, *ION transport (Biology), *LITHIUM, *ION channels

Abstract

[Display omitted] • Smart COF membranes were constructed via biomimetic nanochannel modulation. • Charged and switchable channels endowed COF membranes with high ion selectivity. • Pore size of photo-responsive COF membranes was controllable at angstrom level. • Photo-responsive COF membranes showed great potential in lithium extraction. Smart nanochannels can regulate ion transport behavior by external stimulus and display precise ion selectivity in biological membrane systems, but constructing artificial membranes with responsive and tunable channel remains a severe challenge. Herein, smart covalent organic framework (COF) membranes decorated with photo-responsive azobenzene derivatives (COF-Azo) were fabricated by a biomimetic nanochannel modulation (BNM) strategy, endowing membranes with charged and switchable sub-nanochannels. Under different wavelength of light, the smart COF-Azo membranes simultaneously exhibited outstanding mono/monovalent and mono/divalent ion selectivity (K+/Li+ ideal selectivity of 17.9 and Li+/Mg2+ ideal selectivity of 24.9) via closing and opening channels. The conversion of effective pore size at angstrom level is realized by photoisomerization of azobenzene. After several photoswitch cycles, the smart membranes still maintained K+/Li+ selectivity of 6.1 and Li+/Mg2+ selectivity of 20.7 in mixed salt solution, exhibiting great potentials in lithium extraction. This work may blaze a trail in constructing photo-responsive nanochannel membranes for energy-efficient ion separation. [ABSTRACT FROM AUTHOR]

Published

2024

6. Copper sulfide and polyelectrolyte decorated textiles for active/passive personal thermal management.

Author

Zhao, Zhiheng, Song, Xudong, Zhang, Qi, Zhang, Yang, Feng, Qiang, Guo, Yuhang, Wu, Hong, and Guo, Shaoyun

Subjects

*COPPER sulfide, *COTTON fibers, *HEAT radiation & absorption, *TEXTILE exhibitions, *ELECTROMAGNETIC shielding, *SULFIDE minerals

Abstract

[Display omitted] • A versatile coating was fabricated based on an electrostatic-coordination strategy. • The textile exhibited excellent solar/Joule heating performances properties. • The textile presented passive radiative heating properties. • The textile could protect the human body effectively in practical environments. • The research brought new insights into the development of PTM devices. The development of multifunctional textile-based personal thermal management devices is a prospective option for accurately warming the human body while effectively reducing energy consumption. However, existing multifunctional thermal management devices still face challenges in terms of high-performance integration. Here, we proposed an electrostatic-coordination-based strategy to fabricate successfully a versatile textile for body warming via sequentially covering cotton fiber with bio-based polyelectrolyte and in-situ grown copper sulfide coatings. The textiles with excellent solar/Joule heating properties and reduced infrared emissivity can efficiently heat the body in various environments and suppress thermal radiation dissipation from the body to the environment. Also, the textile realizes high-performance integration of electromagnetic shielding, UV protection, antimicrobial, and flame-retardant properties. This universal and efficient strategy provides a promising solution for the manufacture of all-day and energy-saving versatile personal thermal management devices, showing great potential for practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

7. Self-healing and recyclable biomass aerogel formed by electrostatic interaction.

Author

Yang, Jiyu, Yi, Longfei, Fang, Xiao, Song, Yongjiao, Zhao, Lijuan, Wu, Jinrong, and Wu, Hong

Subjects

*ELECTROSTATIC interaction, *POROUS materials, *ITACONIC acid, *AQUEOUS solutions, *AEROGELS, *CESIUM isotopes

Abstract

The self-healable biomass aerogel is achieved by electrostatic interaction between the chitosan (CS) and itaconic acid (IA). Once the aerogel is cut apart, it can repair both its structure and mechanical performance within 30 s at room temperature via treatment of wetting. After self-healing for 100 s, it can even bear a weight which is almost 3300-fold heavier than the original weight of the aerogel itself. • Disclosing a new strategy for the fabrication of self-healable aerogels. • Ultrafast self-healing capacity was achieved under the stimulus of water. • CSA aerogels display excellent recyclability. • Showing outstanding mechanical property before and after self-healing. Achieving self-healing capacity in porous materials is highly attractive, but still remains a huge challenge. Here we disclosed a new strategy for the fabrication of self-healable biomass aerogels, which is achieved by assembling the positively charged chitosan (CS) and negatively charged itaconic acid (IA) in aqueous solution, followed by a freeze-drying process. Due to relatively strong electrostatic interaction and unique morphology, the aerogel shows outstanding mechanical property even at very low apparent density. More importantly, it possesses ultrafast self-healing ability at room temperature. Once the aerogel is cut apart, it can repair both its structure integrity and mechanical performance within 30 s at room temperature via wetting one fractured surface. After self-healing, its compression strength is almost twice the value of the original one. In addition, the aerogel can be completely dissolved and reshaped, thus displaying excellent recyclability of the materials. Since both CS and IA are derived from natural resources, this work provides a promising solution to the fabrication of self-healable biomass aerogels with both high-performance and sustainability. [ABSTRACT FROM AUTHOR]

Published

2019

8. Thermoelectricity of n-type MnBi4S7-7xSe7x solid solution.

Author

Xi, Ming, Zhu, Huaxing, Wu, Hong, Yang, Yibin, Yan, Yanci, Wang, Guoyu, Wang, Guiwen, Li, JiangYu, Lu, Xu, and Zhou, Xiaoyuan

Subjects

*THERMOELECTRICITY, *THERMAL conductivity, *N-type semiconductors, *CARRIER density, *ELECTRON donors, *THERMOELECTRIC materials, *ELECTRIC conductivity, *SOLID solutions

Abstract

The n-type sulfur-based material MnBi 4 S 7 exhibits intrinsically low thermal conductivity, which is well explained by double well potential. Se alloying can enlarge the carrier concentration and reduce lattice thermal conductivity, resulting in a peak zT value of 0.31, which reveals a record high value among earth-abundant ternary n-type sulfides. • Systematic investigation of the thermoelectric properties of MnBi 4 S 7-x Se x solid solutions. • Elucidation of low lattice thermal conductivity by first-principle calculations and other advanced experimental techniques. • Potential as competitive n type thermoelectric candidate demonstrated by a peak zT of 0.31. We report self-doped MnBi 4 S 7-x Se 7x solid solution as a novel n-type sulfide thermoelectric material with weak anisotropic transport properties. These compounds feature intrinsically low lattice thermal conductivity of 0.5–0.8 W m−1K−1 in the temperature range of 300–800 K, which is well explained by strong lattice anharmonic vibration, mainly from Bi atoms as verified by theoretical calculations. Intentionally introduced sulfur deficiency acts as an efficient electron donor that enhances the electrical conductivity of MnBi 4 S 7 while alloying with Se can promote electrical conductivity and further reduce thermal conductivity by 25% in the whole temperature region. As a result, the sample of with nominal composition of MnBi 4 S 5.46 Se 1.4 shows a peak zT of ~0.31 at 770 K vertical to the pressing direction. [ABSTRACT FROM AUTHOR]

Published

2020

9. Low magnetic field-induced alignment of nickel particles in segregated poly(l-lactide)/poly(ε-caprolactone)/multi-walled carbon nanotube nanocomposites: Towards remarkable and tunable conductive anisotropy.

Author

Shi, Yu-Dong, Yu, Hai-Ou, Li, Jie, Tan, Yan-Jun, Chen, Yi-Fu, Wang, Ming, Wu, Hong, and Guo, Shaoyun

Subjects

*MAGNETIC fields, *NICKEL, *NANOCOMPOSITE materials, *ELECTRIC conductivity, *COMPOSITE materials

Abstract

Anisotropic conductive composites with segregated conductive networks were constructed in poly( l- lactide)/poly(ε-caprolactone)/multi-walled carbon nanotubes/nickel (PLLA/PCL/MWCNT/Ni) composites by aligning Ni particles using a low magnetic field. Firstly, MWCNTs were melt-mixed with PLLA to form PLLA/MWCNT composites and then pulverized into microscale PLLA/MWCNT particles 425–850 μm in size. Later, the Ni particles were dispersed in PCL to yield PCL/Ni composites and then mixed with PLLA/MWCNT particles at 100 °C, a temperature lying in between the melting temperatures of PCL and PLLA. The coated PLLA/MWCNT particles were compressed to form PLLA/PCL/MWCNTs/Ni composites with segregated structures. A remarkable conductive anisotropy was observed in the segregated samples after magnetic alignment in a low magnetic field of ∼47.5 mT at 100 °C for 30 min. The electrical conductivity of the segregated samples diametrically increased in the direction parallel to the magnetic field, but decreased in the direction perpendicular to the magnetic field after the magnetic alignment of Ni particles in the PCL phase. Electrical conductivity in the parallel direction was almost eight orders of magnitude higher than that in the perpendicular direction at 3.0 wt% Ni and 0.7 wt% MWCNTs. Conductive anisotropy in the segregated systems could also be easily regulated by controlling the treatment time or changing the direction of the magnetic field. However, electrical conductivity could be maintained in both vertical and parallel directions in conventional composites after magnetic treatment because Ni particles preferably dispersed in the continuous PLLA phase, in which the Ni particles cannot be aligned at 100 °C. In addition, these segregated samples with alignment of Ni particles also exhibited the mechanical enhancement and high-performance electromagnetic interference shielding. [ABSTRACT FROM AUTHOR]

Published

2018

10. Preparation of a novel nanobiocatalyst by immobilizing penicillin acylase onto magnetic nanocrystalline cellulose and its use for efficient synthesis of cefaclor.

Author

Huang, Zi-Xuan, Cao, Shi-Lin, Xu, Pei, Wu, Hong, Zong, Min-Hua, and Lou, Wen-Yong

Subjects

*CELLULOSE, *ENZYMES, *CEFACLOR, *ENCAPSULATION (Catalysis), *PHOSPHINE, *COUPLING reactions (Chemistry), *PH effect

Abstract

Magnetic nanocrystalline cellulose (MNCC) was prepared and used as an enzyme support for the immobilization of penicillin acylase (PA). A novel coupling agent, tri(hydroxymethyl)phosphine(THP) instead of the conventional glutaraldehyde(GA), was used as a crosslinker in this study. The obtained results showed that the immobilized PA with THP (PA-THP-MNCC) had high enzyme loading (172.3 mg/g) and activity recovery (77.6%) in the optimal preparation conditions, which were remarkably superior to those of the counterpart using GA (PA-GA-MNCC, 148.4 mg/g and 48.7%, respectively). Compared with free PA and PA-GA-MNCC, PA-THP-MNCC displayed a higher optimum pH and temperature, and manifested relatively higher enzyme-substrate affinity and catalytic efficiency. In addition, PA-THP-MNCC exhibited significantly enhanced stability. Furthermore, PA-THP-MNCC was successfully employed for synthesis of cefaclor, an important second-generation cephalosporin antibiotic, affording a significantly higher yield of 84% than that reported previously. [ABSTRACT FROM AUTHOR]

Published

2018

11. In-doping induced resonant level and thermoelectric performance enhancement in n-type GeBi2Te4 single crystals with intrinsically low lattice thermal conductivity.

Author

Chen, Peng, Zhang, Bin, Zou, Hanjun, Gong, Xiangnan, Yan, Yanci, Li, Jingwei, Zhang, Daliang, Han, Guang, Lu, Xu, Wu, Hong, Zhou, Yun, Zhou, Xiaoyuan, and Wang, Guoyu

Subjects

*SINGLE crystals, *N-type semiconductors, *THERMOELECTRIC power, *SEEBECK coefficient, *THERMOELECTRIC materials, *GROUP velocity, *THERMAL conductivity, *PHONON scattering

Abstract

• Growth of large-sized Ge 1– x In x Bi 2 Te 4 single crystals by Bridgman method. • Ultralow κ L of GeBi 2 Te 4 driven by cation disorder and low phonon velocity. • Resonant level introduced by In-doping greatly improves electrical performance. • Achieving zT ave of 0.36 in the range of 323–573 K for Ge 0.97 In 0.03 Bi 2 Te 4 sample. Resonant level, the impurity level located inside the valence/conduction band, is an effective strategy for decoupling the electrical conductivity and Seebeck coefficient and enhancing the thermoelectric power factor. In this work, we show that In doping induces resonant level and enhances the thermoelectric performance of GeBi 2 Te 4 , a promising n-type thermoelectric material with layered structure. Single crystals grown by Bridgman method were used in this study to take the advantage of its anisotropic transport properties. An ultralow lattice thermal conductivity of ∼0.51 W m−1 K−1 at 323 K was found along the c -axis of GeBi 2 Te 4 , driven by intrinsic cation disorder and the low phonon group velocity from the relatively weak chemical bonds as well as the strong lattice anharmonicity caused by hierarchical bond orders. Both enhanced electrical conductivity and Seebeck coefficient were observed in the In-doped samples, indicating that In-doping not only increases the carrier concentration, but also introduces the resonant level that was further confirmed by the first-principles calculation. A maximum zT of ∼0.42 at 523 K and an average zT of 0.36 over 323 to 573 K were achieved in Ge 0.97 In 0.03 Bi 2 Te 4 crystal sample, ∼100% and ∼89% enhancement compared to those of pristine single crystal sample, respectively. This study demonstrates another example of resonant level for thermoelectric performance enhancement, which may be applied to other related materials. [ABSTRACT FROM AUTHOR]

Published

2023

12. Achieving high-efficiency and robust 3D thermally conductive while electrically insulating hybrid filler network with high orientation and ordered distribution.

Author

Zhang, Xiaomeng, Zhang, Jiajia, Xia, Lichao, Wang, Jianfeng, Li, Chunhai, Xu, Fang, Zhang, Xianlong, Wu, Hong, and Guo, Shaoyun

Subjects

*THERMAL conductivity, *ELECTRICAL resistivity, *FILLER materials, *ELECTRIC insulators & insulation, *SILICON carbide

Abstract

Continuous and robust filler network is very critical in improving thermal conductivity of the thermally conductive yet electrically insulating composite. Regrettably, such network is commonly constructed by large amount of thermally conductive while electrically insulating fillers with sacrificing mechanical properties of the final composite. In the present work, to address this issue and further improve the thermally conductive property, the robust 3D thermally conductive while electrically insulating hybrid filler network with high orientation and ordered distribution was constructed successfully through strong shear and extension flow field in confined space during the multilayer co-extrusion. In the hybrid filler network with the 32-layer alternating structure, along the extrusion direction, graphite (Gt) flakes were highly oriented; meanwhile, along the thickness direction, the local Gt-MWCNTs network was confined between two adjacent SiC-filled layers. As a result, thermal conductivity of the final composite reached as high as 2.05 W/(m × K). Furthermore, significantly anisotropic electrical resistivities were also obtained, which endowed the final composite with excellent electrical insulation, great anti-static and electromagnetic interference shielding properties. Moreover, compared with commonly compounded composites, mechanical properties of the multilayered composite were also enhanced significantly. As a consequence, the multifunctional composite with robust thermally conductive while electrically insulating filler network and excellent mechanical properties can be obtained based on this strategy, thus it plays a critical role in facilitating the development of the thermal management materials. [ABSTRACT FROM AUTHOR]

Published

2018

13. Endowing the high efficiency thermally conductive and electrically insulating composites with excellent antistatic property through selectively multilayered distribution of diverse functional fillers.

Author

Zhang, Xiaomeng, Zhang, Jiajia, Li, Chunhai, Wang, Jianfeng, Xia, Lichao, Xu, Fang, Zhang, Xianlong, Wu, Hong, and Guo, Shaoyun

Subjects

*THERMAL conductivity, *PACKAGING materials, *ELECTRONIC equipment, *ANISOTROPY, *ELECTRICAL resistivity

Abstract

To fabricate thermally conductive while electrically insulating composites with excellent antistatic property is a huge challenge in the region of packaging materials of electronic devices due to the contradiction between the electrical insulation and the antistatic property. In the present work, the peculiar multilayer structures with alternating high efficiency thermally, electrically conductive layers and thermally conductive, electrically insulating layers were constructed successfully through a simple, one-step melt extrusion method. Such thermally conductive and electrically insulating composites possessed significant anisotropic electrical resistivity; for example, the in-plane electrical resistivities (parallel to the layer direction) were below 117 Ω × cm, while the through-plane electrical resistivities were over 5 × 10 13 Ω × cm. Meanwhile, with increasing the layer number, thermal conductivity of the composite with the same filler loading was improved monotonously, and reached as high as 1.45 W/(m × K) in the composite with 32 layers. In addition, tensile strength and elongation at break of the composites were also enhanced due to the different deformation mechanisms of separate layers. Furthermore, to give a deep insight into the enhancement mechanism of thermally conductive property, finite element analysis was applied and the results indicated that high efficiency thermally, electrically conductive layers possessed magnified effects on the heat dissipation. Therefore, the multilayer structure with alternating high efficiency thermally, electrically conductive layers and thermally conductive, electrically insulating layers can endow the composite with excellent comprehensive properties effectively, and it also sheds light on the design and fabrication of high performance materials for the applications of thermal management or other energy harvesting fields. [ABSTRACT FROM AUTHOR]

Published

2017

14. Polycarbonate toughening with reduced graphene oxide: Toward high toughness, strength and notch resistance.

Author

Wang, Jianfeng, Li, Chunhai, Zhang, Xiaomeng, Xia, Lichao, Zhang, Xianlong, Wu, Hong, and Guo, Shaoyun

Subjects

*POLYCARBONATES, *GRAPHENE oxide, *STRENGTH of materials, *TENSILE strength, *IMPACT (Mechanics)

Abstract

The toughening effect of graphene sheets on polycarbonate (PC) was investigated to fabricate PC composites with excellent balanced toughness, notch resistance as well as strength. The reduced graphene oxide (RGO) was incorporated into PC matrix through melt compounding. A maximum toughening effect was observed in PC/RGO (PCG) composites with 0.03 wt% or 0.07 wt% RGO. Particularly, the tensile fracture toughness of PCG composites with 0.03 wt% RGO was enhanced by 89%. The notched impact strength and K IC of PCG composite with 0.07 wt% RGO was increased by 46% and 58%, respectively. The point of 0.1 wt% was found to be the ductile-brittle transition point in PCG composites. Meanwhile, the yield strength of these novel materials was increased by around 12% as well at loading of 0.07 wt%. Microcrack, resulting from interfacial debonding between PC and RGO as well as breakage and pulling out of graphene layer, was proposed to be the main toughening mechanism contributing to the great enhanced fracture toughness and notch resistance. Apart from the microcrack, crack pinning, crack deflection and crack arresting were also found and proposed to be toughening mechanism in notch-fractured process. This work not only provides us a novel strategy to fabricate advanced PC nanocomposites but also gives us a deep understanding on the toughening role of graphene on polymers. [ABSTRACT FROM AUTHOR]

Published

2017

15. Anti-scaling covalent organic framework membranes with custom-tailored nanochannels for efficient lithium extraction.

Author

Ren, Liang, Chen, Jianxin, Han, Jian, Liang, Jinsheng, and Wu, Hong

Subjects

*LITHIUM, *SURFACE properties, *GYPSUM

Abstract

[Display omitted] • Ion selective COFMs were constructed via custom-tailored nanochannels strategy. • Charged, narrowed and lithiophilic channels endowed COFMs with high selectivity. • Positively charged surface prevented scaling formation on the COFMs. • The anti-scaling COFMs showed great potential in lithium extraction. Covalent organic framework membranes (COFMs) with well-defined nanochannels have infinite potential in efficient separation. However, unsuitable pore size and easily contaminated surface hamper the application of COFMs for ion separation. Herein, we report a custom-tailored nanochannels strategy for forming COF nanosheets (COFNs) with positively charged, narrowed and lithiophilic channels. The obtained COFNs can be easily assembled into free-defect and oriented COFMs via vacuum-assisted filtration method. Charged and narrowed channels augment entrance resistance of divalent cation, meanwhile, lithiophilic groups promote transport of Li+ in channels. Besides, positively charged surface disturbs the crystallization of scaling. Thus, the optimal COFM exhibited excellent water permeance of 32.1 L m−2 h−1 bar−1 and high Li+/Mg2+ separation factor of 30.2 in simulated salt-lake brine. After running in the gypsum solution, the anti-scaling COFMs showed low flux decline ratio (FDR) and the flux recovery ratio (FRR) was nearly 10% higher than NF90. This study may provide a facile regulation method for nanochannels and surface properties of COFMs, and the obtained membranes could be applied to efficient lithium extraction. [ABSTRACT FROM AUTHOR]

Published

2023

16. High-titer production of myo-inositol by a co-immobilized four-enzyme cocktail in biomimetic mineralized microcapsules.

Author

Han, Pingping, You, Chun, Li, Yunjie, Shi, Ting, Wu, Hong, and Zhang, Yi-Heng P. Job

Subjects

*SYNTHETIC enzymes, *INDUSTRIAL capacity, *INOSITOL, *POLYETHYLENEIMINE, *PRICES, *COSMETICS industry

Abstract

[Display omitted] • First attempt to realize high-titer production of inositol by co-immobilized multi-enzymes. • An inositol titer of up to 210 g/L was produced. • Prolonged enzyme lifetime decreased biomanufacturing cost. • Scaleable multienzyme immobilization for potential industrial application was proposed. Myo -inositol is widely used in food, feed, pharmaceutical and cosmetic industries, but its great potentials are restricted from its limited supplies and high prices. Inositol is the first biobased product produced by the in vitro biomanufacturing platform containing multi-enzymes in one pot on an industrial scale. However, the in vitro multi-enzyme-based biomanufacturing face the challenge of enzyme deactivation and high cost of the enzymes used. To further prolong the enzyme lifetime and decrease its biomanufacturing cost, here we developed a co-immobilized four-enzyme cocktail using biomimetic mineralized microcapsules composed of polyethyleneimine and silicate for large-scale production. The lumped enzyme half-life of the microcapsules was 55.5 h at 70 °C, which was 5.9 folds of that of the four-enzyme cocktail. An inositol titer of up to 210 g/L was produced, and the cost of enzymes used was decreased by 3.4 times. This is the first attempt to realize high-titer production of inositol by co-immobilized multi-enzymes, laying a foundation of in vitro biomanufacturing based on in vitro synthetic enzyme biosystems. [ABSTRACT FROM AUTHOR]

Published

2023

17. Photoactivation-triggered in situ self-supplied H2O2 for boosting chemodynamic therapy via layered double Hydroxide-mediated catalytic cascade reaction.

Author

Guo, Zhenhu, Xie, Wensheng, Zhang, Qianyi, Lu, Jingsong, Ye, Jielin, Gao, Xiaohan, Xu, Wanling, Fahad, Abdul, Xie, Yike, Wei, Yen, Wu, Hong, Boyer, Cyrille, Zhao, Lingyun, and Gu, Zi

Subjects

*LAYERED double hydroxides, *PHOTODYNAMIC therapy, *HYDROXYL group, *REACTIVE oxygen species, *HYDROXIDES, *TUMOR treatment

Abstract

• A photo-activated chemodynamic therapy (CDT) was developed for cancer treatment. • A nanosheet catalyst was constructed to enable cascade catalytic reactions. • Superoxide radicals generated from photodynamic therapy was converted into H 2 O 2. • In-situ generated and endogenous H 2 O 2 induced ·OH generation for enhanced CDT. Chemodynamic therapy (CDT) has aroused extensive interest as an advanced anti-cancer approach which is featured with high tumor specificity and selectivity. However, chemodynamic therapeutic efficacy heavily relies on the level of endogenous hydrogen peroxide (H 2 O 2), which is intrinsically heterogenous and insufficient. Herein, a self-supplied H 2 O 2 enhanced chemodynamic therapeutic strategy is developed by constructing a two-dimensional (2D) sheet-like nanocatalyst to mediate catalytic cascade reactions. The cascade nanocatalyst is fabricated by integrating photosensitizer indocyanine green (ICG) and Fenton reaction catalyst Fe2+ ions into a 2D ultrathin layered double hydroxide nanoparticles (NPs). Under near infrared light irradiation, ICG not only produces cytotoxic singlet oxygen (1O 2) to damage tumor cells, but also generates superoxide radical (O 2 ·-) that is subsequently converted into H 2 O 2 by reacting with intracellular superoxide dismutase (SOD). A considerable amount of in situ self-supplied H 2 O 2 , together with endogenous H 2 O 2 , is then catalyzed by Fe2+ released from nanocatalyst to produce abundant, highly cytotoxic hydroxyl radicals (· OH) to trigger apoptosis and death of tumor cells. In vitro and in vivo evaluations manifest the cascade nanocatalyst-mediated remarkable chemodynamic therapeutic performance. Therefore, this work has demonstrated a cascade catalytic therapeutic nanoplatform enabling photoactivation-triggered H 2 O 2 self-supplied synergistic strategy for safe and efficacious tumor treatment. [ABSTRACT FROM AUTHOR]

Published

2022

18. Three-dimensional nitrogen-doped graphene oxide beads for catalytic degradation of aqueous pollutants.

Author

Hirani, Rajan Arjan Kalyan, Asif, Abdul Hannan, Rafique, Nasir, Wu, Hong, Shi, Lei, Zhang, Shu, Duan, Xiaoguang, Wang, Shaobin, Saunders, Martin, and Sun, Hongqi

Subjects

*GRAPHENE oxide, *POLLUTANTS, *MICROPOLLUTANTS, *ELECTRON paramagnetic resonance, *SEWAGE disposal plants, *HYDROXYBENZOIC acid

Abstract

[Display omitted] • Nitrogen-doped reduced graphene oxide beads (NrGOb) were fabricated by a one-step self-assembly strategy. • The lightweight NrGOBs and peroxymonosulfate system presented high activity in oxidative degradation of organic pollutants. • The catalytic beads were packed in a fixed-bed column reactor to maintain a continuous process. • Reactive radicals were identified by the quenching tests and electron paramagnetic resonance spectra. • Mechanistic studies on peroxymonosulfate activation and degradation pathways of hydroxybenzoic acid were performed. Metal-free graphene-based catalysts have demonstrated excellent performance in advanced oxidation processes (AOPs). However, the recovery and reusability of these nanocatalysts are still a major issue. In this study, three dimensional (3D) nitrogen-doped reduced graphene oxide beads (NrGOb) were synthesized via a self-assembly method and then applied in heterogeneous activation of peroxymonosulfate (PMS) for the oxidation of hydroxybenzoic acid (HBA). The materials (NrGOb) were annealed at various temperatures ranging from 500 to 1000 °C, and the resulting NrGOb derived from 800 °C (NrGOb-800) exhibited the best performance for PMS activation. To avoid the challenging recovery, the degradation experiments were also performed in a packed-bed catalytic reactor. Various reaction parameters were investigated to optimize the efficiency of the system. Electron paramagnetic resonance (EPR) and quenching tests were carried out to differentiate the contribution of reactive radicals (SO 4 •- and •OH) in the degradation process and then aided in illustrating the degradation mechanism. Finally, the stability and reusability of the catalytic beads were investigated. The efficiency slightly declined with increased cycles; however, catalyst regeneration would be able to partially restore the active sites. The results suggest the feasibility of exploiting graphene-based macrostructures on the AOPs platform for the degradation of organic pollutants in commercial wastewater treatment plants. [ABSTRACT FROM AUTHOR]

Published

2022

19. Confined facilitated transport within covalent organic frameworks for propylene/propane membrane separation.

Author

Jiang, Haifei, Chen, Yu, Song, Shuqing, Guo, Zheyuan, Zhang, Zhengqing, Zheng, Chenyang, He, Guangwei, Wang, Hongjian, Wu, Hong, Huang, Tong, Ren, Yanxiong, Liu, Xin, Zhang, Junfeng, Yin, Yan, Jiang, Zhongyi, and Guiver, Michael D.

Subjects

*MEMBRANE separation, *PROPENE, *SEPARATION of gases, *COMPOSITE membranes (Chemistry), *ALKENES, *PROPANE, *PARAFFIN wax

Abstract

[Display omitted] • COF-based membranes are utilized for C 3 H 6 /C 3 H 8 separation for the first time. • Large-sized COF pores can achieve maximum contact between Ag+ and C 3 H 6 molecules. • High-density Ag+ facilitates C 3 H 6 confined transport along nanochannel surface. • Density differences result in asymmetric structure and directional transport. • Confined mechanism with asymmetric structure provide superior separation performance. Energy-efficient membrane technology is sought to replace or integrate with conventional energy- and cost-intensive distillation for precise propylene/propane separation. Covalent organic framework (COF)-based composite membranes (CMs) are promising candidates for the representative difficult propylene/propane separation system. However, the large-size pore of COFs cannot achieve an effective separation of gas pairs with sub-angstrom (0.2 Å) size differences. Here, we design confined facilitated transport nanochannels within COFs as productive fillers to construct CMs. The anchored high-density Ag+ carriers facilitate C 3 H 6 monomolecular high-speed transport along the nanochannel surface. Under this confined transport mechanism, the problem of over-sized COF pores can be partially circumvented, and high selectivity obtained. Moreover, the obtained asymmetric configuration of SCOF-Ag/PI CMs results in directional gas transport. As the first work of COF-based membranes for olefin/paraffin separation, SCOF-Ag/PI CMs demonstrate a high propylene permeability of 75.16 barrer and good propylene/propane selectivity of 35.45, out-performing most of the polymer-based membranes and approaching the performance of ZIF-8 membranes. Furthermore, SCOF-Ag/PI CMs exhibit over one-month durability. The excellent separation performance combined with operating stability provides a promising alternative approach toward efficient C 3 H 6 /C 3 H 8 separation. [ABSTRACT FROM AUTHOR]

Published

2022

20. Morphology/facet-dependent photo-Fenton-like degradation of pharmaceuticals and personal care products over hematite nanocrystals.

Author

Asif, Abdul Hannan, Rafique, Nasir, Hirani, Rajan Arjan Kalyan, Wu, Hong, Shi, Lei, Zhang, Shu, Wang, Shaobin, Yin, Yu, Saunders, Martin, and Sun, Hongqi

Subjects

*HEMATITE, *HYGIENE products, *NANOCRYSTALS, *NUCLEAR energy, *SURFACE energy, *PHOTOCATALYSTS

Abstract

[Display omitted] • α-Fe 2 O 3 of cuboid/rhombohedral, spheroidal, rice-like, and plate-like were synthesised. • Photo-Fenton-like degradation of p-hydroxybenzoic acid (p-HBA) and sulfachloropyridazine (SCP) was conducted. • Correlation among atomic configuration of the exposed facets, specific surface area and photocatalytic activity was established. • Degradation mechanism and pathways for p-HBA and SCP were proposed. Hematite (α-Fe 2 O 3) with different shapes and preferentially exposed facets may differ in surface energy and atomic configuration resulting in versatile catalysis. Herein, four morphologies of α-Fe 2 O 3 nanocrystals, e.g. cuboid/rhombohedral, spheroid, rice-like, and plate-like are synthesised by hydrothermal/solvothermal routes. The correlation between morphology and photochemical performance is established by investigating the photo-Fenton-like degradation of p-hydroxybenzoic acid (p-HBA) and sulfachloropyridazine (SCP). The plate-like sample demonstrates the highest removal efficiency, whereas the normalised reaction rate by specific surface area shows the reaction order as cuboid/rhombohedral > plate-like > spheroid > rice-like. This can be ascribed to the synergistic role of the surface atomic arrangement and specific surface area. The main reactive species and degradation pathways were studied in detail. The research findings may offer new insights into the morphology/facet-dependent photochemical remediation of emerging contaminants (ECs) on α-Fe 2 O 3. [ABSTRACT FROM AUTHOR]

Published

2022

21. Sintered Ni metal as a matrix of robust self-supporting electrode for ultra-stable hydrogen evolution.

Author

Zhao, Yang, Wei, Shizhong, Xia, Liangbin, Pan, Kunming, Zhang, Bin, Huang, He, Dong, Zhili, Wu, Hong-Hui, Lin, Junpin, and Pang, Huan

Subjects

*STANDARD hydrogen electrode, *POROUS metals, *POWDER metallurgy, *FOAM, *HYDROGEN evolution reactions, *CATALYST supports, *METALS, *METALLIC composites

Abstract

A novel porous sintered Ni metal as the matrix for supporting MoS 2 /Ni 3 S 2 hierarchical nanorods is successfully prepared by powder metallurgy and hydrothermal sulfurization. The porous sintered Ni-metal matrix supported with the MoS 2 /Ni 3 S 2 displays more advantages over Ni foam, including enhanced catalytic activity and stability, as well as the sufficient mechanical properties, which can be beneficial for the industrial service. [Display omitted] • The porous Ni metal substrate is fabricated via powder metallurgy. • The catalyst of MoS 2 /Ni 3 S 2 with hierarchical structures is confirmed. • The catalytic activity, conductivity and stability for HER are improved. • The self-supporting electrode exhibits sufficient mechanical properties. • NiO controlled by the annealing temperature determines the morphology. For the self-supporting catalysts of Hydrogen evolution reaction (HER), the rational design and fabrication of substrate with porous structure and sufficient mechanical strength are critical to promoting the industrial HER application. In this work, a novel porous sintered Ni metal as the matrix for supporting catalysts was successfully prepared by powder metallurgy, and a self-supporting electrode for HER was fabricated via a simple sulfurization process on this sintered Ni metal matrix. For instance, MoS 2 /Ni 3 S 2 nanorods (NRs) were vertically grown on the as-sintered porous Ni matrix, and the morphology of the sintered Ni matrix significantly affected the growth of MoS 2 /Ni 3 S 2 NRs. The NRs@Sintered Ni electrode shows a low overpotential of η10 = 56 mV and Tafel slope of 82 mV dec−1. Compared with NRs@Ni foam, the NRs@Sintered Ni exhibits superior stability, where no exfoliation and cracks are observed on the surface of the electrode after 5000 CV cycles. Ultra-high stability and long-term durability are obtained over 100 h even at high potentials of 200 and 300 mV. Moreover, the tensile strength of the as-obtained electrode based on the sintered Ni manifests nearly 260 times higher than that of NRs@Ni foam, evidencing an excellent mechanical property. This work provides an idea for the preparation of self-supporting metal-based catalytic electrodes in large-scale hydrogen production. [ABSTRACT FROM AUTHOR]

Published

2022

22. Self-supporting transition metal chalcogenides on metal substrates for catalytic water splitting.

Author

Zhao, Yang, Wei, Shizhong, Pan, Kunming, Dong, Zhili, Zhang, Bin, Wu, Hong-Hui, Zhang, Qiaobao, Lin, Junpin, and Pang, Huan

Subjects

*TRANSITION metal chalcogenides, *PROBLEM solving, *GOLD, *CATALYST supports, *METALS, *CHEMICAL properties

Abstract

The review summarizes the typical synthetic strategies, morphologies, catalytic performances, mechanisms, application conditions and scope of various metallic matrices, such as Au, Mo, Ni, and Ti, for supporting TMCs catalysts. The development directions and outlook of self-supporting TMCs@Metal electrodes for large-scale preparation and catalytic water splitting in industrial applications are discussed in detail. [Display omitted] • The self-supporting catalytic electrodes for water splitting are studied. • The electrodes classified according to different substrates are summarized. • The loaded TMC materials and preparation strategies are discussed in detail. • The prospects of TMCs@Metal electrodes for industrial applications are suggested. Transition metal chalcogenides (TMCs) are the fascinating replacement of noble catalysts in catalytic water splitting due to their unique physical and chemical properties and low cost. However, their industrial application is substantially restricted by their poor conductivity. Decorating TMCs on metal substrates to fabricate self-supporting electrodes could be an efficient strategy for solving this problem. In this review, typical synthetic strategies for self-supporting TMCs on metal substrates are introduced in detail, while all types of metallic matrices, such as Au, Mo, Ni, Ti, Cu, etc., for supporting TMC catalysts are comprehensively summarized. By comparing the matrix types, types of loaded TMC materials, preparation strategies, application conditions, and scope, we attempt to establish rules of various metals as substrates, which may provide suggestions for material design. Finally, we briefly discuss the development directions of self-supporting TMCs@Metal electrodes for large-scale preparation and catalytic water splitting in industrial applications. [ABSTRACT FROM AUTHOR]

Published

2021

23. Mechanically robust microporous anion exchange membranes with efficient anion conduction for fuel cells.

Author

Huang, Tong, Zhang, Junfeng, Pei, Yabiao, Liu, Xin, Xue, Jiandang, Jiang, Haifei, Qiu, Xiaoyu, Yin, Yan, Wu, Hong, Jiang, Zhongyi, and Guiver, Michael D.

Subjects

*FUEL cells, *OPEN-circuit voltage, *ANIONS, *MOLECULAR weights, *ION exchange (Chemistry), *MICROPOROSITY

Abstract

• Brittleness in polymer of intrinsic microporosity (PIM) membranes is alleviated by high molecular weight. • Role of micropores in developing water/ion conduction channels is investigated. • Microporous anion exchange membrane (AEM) has superior ion conduction efficiency. • H 2 crossover through microporous AEM is minimal in the hydrated state. • Feasibility of microporous AEMs for H 2 /O 2 fuel cell is evaluated. Polymers of intrinsic microporosity (PIMs) present an attractive opportunity for developing new types of anion exchange membranes (AEMs) for fuel cell featuring charged subnanometer-sized micropores. But challenges exist to make mechanically robust PIM AEMs due to their high chain rigidity. Imparting more flexibility improves mechanical properties but sacrifices microporosity. Here, a mechanically robust and highly anion conductive PIM AEM (QPIM-1) fabricated by facile animation and quaternization of PIM-1 membrane is reported, and its structure–property relationships are investigated, especially focusing on the microporous structure. High molecular weight alleviates brittleness, as QPIM-1 AEM shows comparable mechanical properties to conventional AEMs, quaternized poly(2,6-dimethyl-1,4-phenylene oxide) (QPPO), at a membrane thickness down to ~35 μm and a high ion exchange capacity (IEC) up to ~2.1 mmol g−1. The micropores situated among the rigid and contorted polymer chains evolve into water/ion conduction channels when the membrane is hydrated. This results in improved morphology over dense polymeric AEMs by less hindered ion pathways. QPIM-1 AEMs exhibit superior ion conduction efficiency, which is 2.6–5.3 times that of dense QPPO AEM at similar ion exchange capacities (IECs). A high hydroxide ion conductivity of 57 mS cm−1 at 20 °C is obtained, which is among the highest reported anion conductive PIM-based AEMs. Even though the AEMs are microporous, only slight H 2 permeation is observed when hydrated and at high open circuit voltage (OCV) of a single fuel cell. [ABSTRACT FROM AUTHOR]

Published

2021

24. Fouling-resistant robust membranes via electrostatic complexation for water purification.

Author

You, Xinda, Xiao, Ke, Yu, Qianqian, Wu, Hong, Yuan, Jinqiu, Zhang, Runnan, Ma, Yu, Li, Yafei, Huang, Tong, and Jiang, Zhongyi

Subjects

*WATER purification, *WATER harvesting, *SURFACE energy, *ORGANIC dyes, *POLYANIONS

Abstract

[Display omitted] • Electrostatic-complexed fluorinated membranes (ECFMs) were fabricated. • Temporally-coordinated complexation regulates physicochemical structure of ECFMs. • ECFM shows high water flux of 93.3 L m−2 h−1 bar−1 and dye rejection over 90.0%. • Spatial and temporal antifouling property of ECFMs was evaluated and elucidated. • Optimized ECFM displays superior antifouling property and long-term stability. Membrane-based separation provides an energetically efficient and environmentally benign solution to water purification. Biomimetic self-assembled membranes affording full-aqueous-phase membrane fabrication built on underwater bioadhesion create a new paradigm to green and controllable membrane fabrication, but currently are obstructed by fouling and stability hurdles. Inspired by the chemical features of charged cement proteins of sandcastle worm, we propose an electrostatic-driven complexation method to fabricate fouling-resistant robust membranes. Phosphorylated polyanion, quaternized polycation and perfluorinated sulfonic acid polyanion are successively assembled onto the porous substrate to obtain electrostatic-complexed fluorinated membranes (ECFMs), where quaternized cellulose serves as a bridging polyelectrolyte to induce and coordinate electrostatic complexation. Temporal complexation generates 84-nm-thick membranes with precisely controlled physicochemical structure, surface energy and spatial interaction with foulants, harvesting ultrahigh water permeance of 93.3 L m−2 h−1 bar−1 with organic dyes (>450 Da) removal over 90.0%, and high fouling resistance ensuring persistently high production of purified water. Unlike the amino protein of traditional bio-cement whose positive charge strongly relies on pH, the environmentally-independent chargeability of quaternary ammonium and hydrophobic fluorine segment synergistically renders the membranes superior adaptability towards various underwater conditions for dozens or hundreds of days. [ABSTRACT FROM AUTHOR]

Published

2021

25. Template-free fabrication of MoP nanoparticles encapsulated in N-doped hollow carbon spheres for efficient alkaline hydrogen evolution.

Author

Li, Jin, Huang, He, Cao, Xinxiang, Wu, Hong-Hui, Pan, Kunming, Zhang, Qiaobao, Wu, Naiteng, and Liu, Xianming

Subjects

*HYDROGEN evolution reactions, *SPHERES, *ALKALINE solutions, *ZETA potential, *CARBON, *HYDROGEN, *TRANSITION metals

Abstract

Based on the synergy between MoP and N-doped carbon, MoP nanoparticles encapsulated in N-doped carbon hollow spheres were synthesized using inorganic-organic hybrids as precursors, which shows an excellent stability and activity with an overpotential 96 mV at 10 mA cm−2 and a small Tafel slope of 53 mV dec−1 in alkaline solution. [Display omitted] • A template-free approach was developed to fabricate MoP@NC hollow microsphere. • Inorganic-organic hybrids were used as precursors. • Remarkable electrocatalytic hydrogen evolution performance could be achieved. • The synergy between MoP and the pyridinic N could optimize the electronic structure. Encapsulating transition metal phosphides into nitrogen-doped carbon (NC) materials is an effective strategy to enhance the electrocatalytic performance. Herein, we develop a novel template-free approach to rationally fabricate molybdenum phosphide (MoP) nanoparticles encapsulated in N-doped carbon (MoP@NC) hollow microspheres for alkaline hydrogen evolution reaction (HER) by employing inorganic-organic hybrids as precursors, in which phosphorus source of the MoP@NC derives from tetra (hydroxymethyl) phosphorus chloride for the first time. The optimized MoP@NC sample shows a low overpotential of 96 mV at 10 mA cm−2, a small Tafel slope of 53 mV dec−1, and excellent stability. The enhanced HER performance is mainly attributed to the integrated effects of a distinctive hollow structure, high pyridinic N-doping level, and the extremely intimate synergy between MoP and NC. Theoretical calculations indicate that the active sites of the catalyst are mainly located at Mo atoms adjacent to the pyridinic N-doped carbon layer (pyridinic-N-MoP); the synergistic interaction between MoP and pyridinic N (rather than pyrrolic or graphitic N) atoms can lower the d band center of Mo, weaken the Mo-H ads bond and thereby enhance HER performance. In addition, the pyridinic N atoms at the interactive sites play a key role in adsorbing H 2 O and preventing the adsorption of OH*, resulting in accelerating the water splitting. This work provides a new method to rationally synthesize high-efficient and stable MoP-based hollow sphere electrocatalysts for alkaline HER through designing inorganic-organic hybrid precursors. [ABSTRACT FROM AUTHOR]

Published

2021

26. Simultaneously enhanced thermal conductivity and mechanical properties of PP/BN composites via constructing reinforced segregated structure with a trace amount of BN wrapped PP fiber.

Author

Li, Xiang, Li, Chunhai, Zhang, Xiaomeng, Jiang, Yuanping, Xia, Lichao, Wang, Jianfeng, Song, Xudong, Wu, Hong, and Guo, Shaoyun

Subjects

*THERMAL conductivity, *BORON nitride, *FIBERS, *TENSILE strength

Abstract

• Constructing fiber reinforced segregated structure. • BN orient along the fiber surface forming robust thermally conductive network. • Simultaneously enhanced thermal conductivity and mechanical properties. Segregated structure with continuous filler network but isolated matrix is a classic prototype to increase the thermal conductivity (TC) of the composites. However, such prototype only finds limited applications due to both the poor mechanical properties originated from the discontinuity of the polymer matrix and the mediately improved TC of the continuous filler network arising from the random contact of the fillers. In this work, a reinforced segregated structure in which the continuous phase is made with boron nitride (BN) wrapped a trace amount of PP fiber (PF), is first proposed in order to enhance the TC and mechanical properties simultaneously. In such reinforced segregated structure, BN aligns on the surfaces of PF thus forms a long-range ordered, high thermal conductive pathway. As expected, an enhancement of 244%, 133% and 103% in the TC, elongation at break and tensile strength of the composite with reinforced segregated structure are successfully achieved compared with typical segregated structure. Therefore, this work offers some new insights into the design of a segregated structure to balance the TC and mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2020

27. Surface engineering of hollow carbon nitride microspheres for efficient photoredox catalysis.

Author

Wang, Shuaijun, Zhao, Hongfei, Zhao, Xiaoli, Zhang, Jinqiang, Ao, Zhimin, Dong, Pei, He, Fengting, Wu, Hong, Xu, Xinyuan, Shi, Lei, Zhao, Chaocheng, Wang, Shaobin, and Sun, Hongqi

Subjects

*HYDROGEN evolution reactions, *NITRIDES, *MICROSPHERES, *CATALYSIS, *PRECIOUS metals, *SILICON nitride, *SEMICONDUCTOR materials, *QUANTUM efficiency

Abstract

Novel hollow carbon nitride microspheres were fabricated and employed for the efficient photocatalytic degradation of p-hydroxybenonic and hydrogen evolution. • Hollow carbon nitride microspheres (HCNMS) were designed and synthesized. • OH-HCNMS exhibited enhanced hydrogen evolution than pristine C 3 N 4 at 420 nm. • HCNMS exhibited 4.3 times faster degradation of organics than pristine C 3 N 4. • The modified LUMO orbital configuration was favorable for electron-hole separation. Photocatalysis has attracted extensive interests because of the potential applications in remedying emerging contaminants and easing ever-increasing energy crisis. Towards practical applications of photocatalysis, exploring competing semiconductor materials is a critical challenge. Herein, hollow carbon nitride microspheres (HCNMS) were synthesized via a template-free hydrothermal approach, in which OH groups (OH-HCNMS) were used for further tuning the surface features. Their properties were thoroughly investigated by a number of advanced characterization methods. The as-prepared HCNMS achieved an impressive p-hydroxybenzoic acid (HBA) degradation rate of 0.013 min−1, which was 4.3 times higher than pristine carbon nitride (C 3 N 4), even higher than some heterostructured or noble metal modified C 3 N 4. The enhanced photooxidation activity of HCNMS was achieved because of the optimized band structure and the deepened valence band edge, as unveiled by both experimental and density functional theory (DFT) calculation results. In addition, OH-HCNMS exhibited an apparent quantum efficiency (AQE) of 3.7% at 420 nm. The improved hydrogen efficiency of OH-HCNMS was ascribed to the surface functionalized OH groups, which react with holes, and release more electrons to participate the water splitting, as well as the modified orbital configuration which facilitates the faster charge carrier transfer. [ABSTRACT FROM AUTHOR]

Published

2020

28. Flame-retardant poly(vinyl alcohol)/MXene multilayered films with outstanding electromagnetic interference shielding and thermal conductive performances.

Author

Jin, Xiuxiu, Wang, Jianfeng, Dai, Lunzhi, Liu, Xiaoya, Li, Lei, Yang, Yanyu, Cao, Yanxia, Wang, Wanjie, Wu, Hong, and Guo, Shaoyun

Subjects

*ELECTROMAGNETIC interference, *ELECTROMAGNETIC shielding, *THERMAL shielding, *POLYVINYL alcohol

Abstract

• PVA/MXene alternating multilayered films were fabricated via multilayered casting. • The multilayered films exhibited high EMI SE of 44.4 dB and SSE t of 9343 dB cm2 g−1. • The multilayered films exhibited a high thermal conductivity of 4.57 W/mK. • The multilayered films showed remarkable anti-dripping performance. With the miniaturized and high-frequency development in electronic products, polymeric films synchronously with high electromagnetic interference (EMI) shielding effectiveness (SE) and thermal conductivity (TC) are urgently needed. In this work, poly (vinyl alcohol)/transition metal carbide (PVA/MXene) films featured with alternating multilayered structure were fabricated through multilayered casting. The continuous MXene layer provided a compact network for conducting heat and electron, endowing the multilayered film with excellent EMI SE and TC synchronously. In particular, the 27-μm-thick PVA/MXene multilayered film (containing 19.5 wt% MXene in total) exhibited an electrical conductivity of 716 S/m, a maximum EMI SE of 44.4 dB and a specific EMI SE (SSE t) of 9343 dB cm2 g−1. Meanwhile, the multilayered film showed a high in-plane TC of 4.57 W/mK, enhanced by almost 23-fold compared with that of neat PVA. Moreover, the multilayered architecture endowed the film with remarkable anti-dripping performance. This work provides a novel and feasible strategy for fabricating flame-retardant polymeric thermal conductive and EMI shielding films, which will have enormous prospect in advanced electrical devices. [ABSTRACT FROM AUTHOR]

Published

2020