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95 results on '"Hu, Xuzhi"'

54. Low‐Dimensional 2‐thiopheneethylammonium Lead Halide Capping Layer Enables Efficient Single‐Junction Methylamine‐Free Wide‐Bandgap and Tandem Perovskite Solar Cells

Author

Guan, Hongling, primary, Zhang, Wenjun, additional, Liang, Jiwei, additional, Wang, Chen, additional, Hu, Xuzhi, additional, Pu, Dexing, additional, Huang, Lishuai, additional, Ge, Yansong, additional, Cui, Hongsheng, additional, Zou, Yuanrong, additional, Fang, Guojia, additional, and Ke, Weijun, additional

Published
2023
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56. Over 28% efficiency perovskite/Cu(InGa)Se2 tandem solar cells: highly efficient sub-cells and their bandgap matching

Author

Liu, Xinxing, primary, Zhang, Junjun, additional, Tang, Liting, additional, Gong, Junbo, additional, Li, Wang, additional, Ma, Zengyang, additional, Tu, Zexin, additional, Li, Yanyan, additional, Li, Ruiming, additional, Hu, Xuzhi, additional, Shen, Chen, additional, Wang, He, additional, Wang, Zhiping, additional, Lin, Qianqian, additional, Fang, Guojia, additional, Wang, Sheng, additional, Liu, Chang, additional, Zhang, Zengming, additional, Li, Jianmin, additional, and Xiao, Xudong, additional

Published
2023
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62. In-Membrane Nanostructuring of Cationic Amphiphiles Affects Their Antimicrobial Efficacy and Cytotoxicity: A Comparison Study between a De Novo Antimicrobial Lipopeptide and Traditional Biocides

Author

Fa, Ke, primary, Liu, Huayang, additional, Gong, Haoning, additional, Zhang, Lin, additional, Liao, Mingrui, additional, Hu, Xuzhi, additional, Ciumac, Daniela, additional, Li, Peixun, additional, Webster, John, additional, Petkov, Jordan, additional, Thomas, Robert K., additional, and Lu, Jian Ren, additional

Published
2022
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63. How do chain lengths of acyl-l-carnitines affect their surface adsorption and solution aggregation?

Author

National Science Foundation (US), Liu, Huayang, Fa, Ke, Hu, Xuzhi, Li, Zongyi, Ma, Kun, Liao, Mingrui, Zhang, Lin, Schweins, Ralf, Maestro, Armando, Li, Peixun, Webster, John R.P., Petkov, Jordan, Thomas, Robert K., Lu, Jianren, National Science Foundation (US), Liu, Huayang, Fa, Ke, Hu, Xuzhi, Li, Zongyi, Ma, Kun, Liao, Mingrui, Zhang, Lin, Schweins, Ralf, Maestro, Armando, Li, Peixun, Webster, John R.P., Petkov, Jordan, Thomas, Robert K., and Lu, Jianren

Abstract

[Hypothesis] l-carnitines in our body systems can be readily converted into acyl-l-carnitines which have a prominent place in cellular energy generation by supporting the transport of long-chain fatty acids into mitochondria. As biocompatible surfactants, acyl-l-carnitines have potential to be useful in technical, personal care and healthcare applications. However, the lack of understanding of the effects of their molecular structures on their physical properties has constrained their potential use., [Experiments] This work reports the study of the influence of the acyl chain lengths of acyl-l-carnitines (CnLC) on solubility, surface adsorption and aggregation. Critical micellar concentrations (CMCs) of CnLC were determined by surface tension measurements. Neutron reflection (NR) was used to further examine the structure and composition of the adsorbed CnLC layer. The structural changes of the micellar aggregates under different concentrations of CnLC, pH and ionic strength were determined by dynamic light scattering (DLS) and small angle neutron scattering (SANS)., [Findings] C12LC is fully soluble over a wide temperature and concentration range. There is however a strong decline of solubility with increasing acyl chain length. The adsorption and aggregation behavior of C14LC was therefore studied at 30 °C and C16LC at 45 °C. The solubility boundaries displayed distinct hysteresis with respect to heating and cooling. The CMCs of C12LC, C14LC and C16LC at pH 7 were 1.1 ± 0.1, 0.10 ± 0.02 and 0.010 ± 0.005 mM, respectively, with the limiting values of the area per molecule at the CMC being 45.4 ± 2, 47.5 ± 2 and 48.8 ± 2 Å2 and the thicknesses of the adsorbed CnLC layers at the air/water interface increasing from 21.5 ± 2 to 22.6 ± 2 to 24.2 ± 2 Å, respectively. All three surfactants formed core–shell spherical micelles with comparable dimensional parameters apart from an increase in core radius with acyl chain length. This study outlines the effects of acyl chain length on the physicochemical properties of CnLCs under different environmental conditions, serving as a useful basis for developing their potential applications.

Published
2022

64. Defects Passivation via Potassium Iodide Post‐Treatment for Antimony Selenosulfide Solar Cells with Improved Performance.

Author

Li, Jiashuai, Gao, Zheng, Hu, Xuzhi, Wang, Shuxin, Liu, Yongjie, Wang, Chen, Dong, Kailian, Zeng, Zhaofeng, Tao, Chen, and Fang, Guojia

Subjects
SOLAR cells, POTASSIUM iodide, PHOTOVOLTAIC power systems, ANTIMONY, PASSIVATION, ANTISITE defects, ABSORPTION coefficients
Abstract

Antimony selenosulfide (Sb2(S,Se)3) has been emerging as a promising light absorber in the past few years owing to tunable bandgap (1.1–1.7 eV), high absorption coefficient (>105 cm−1) and excellent phase and environmental stability. However, the efficiency of Sb2(S,Se)3 solar cells lags far behind the Shockley–Queisser limit. One of the critical obstacles originates from various extrinsic and intrinsic defects. They mostly locate in the deep energy levels and are prone to form recombination centers, inhibiting the improvement of device performance. Herein, surface post‐treatment via potassium iodide is introduced to fabricate high‐quality Sb2(S,Se)3 films and solar cells. The surface post‐treatment not only manipulates the crystal growth process to form compact films with larger grain size but also forms better band alignment and inhibits the formation of deep‐level defects antimony antisite (SbSe), thus improving the quality of heterojunction. Consequently, the resultant Sb2(S,Se)3 solar cells achieve a champion power conversion efficiency of 9.22%. This study provides a new strategy of passivating deep‐level intrinsic defects via surface post‐treatment for high‐efficiency Sb2(S,Se)3 solar cells. [ABSTRACT FROM AUTHOR]

Published
2023
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68. Revealing the Mechanism of π Aromatic Molecule as an Effective Passivator and Stabilizer in Highly Efficient Wide‐Bandgap Perovskite Solar Cells

Author

Liang, Jiwei, primary, Chen, Cong, additional, Hu, Xuzhi, additional, Xiao, Meng, additional, Wang, Chen, additional, Yao, Fang, additional, Li, Jing, additional, Wang, Haibing, additional, He, Jingwang, additional, Da, Bo, additional, Ding, Zejun, additional, Ke, Weijun, additional, Tao, Chen, additional, and Fang, Guojia, additional

Published
2021
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70. Structural Disruptions of the Outer Membranes of Gram-Negative Bacteria by Rationally Designed Amphiphilic Antimicrobial Peptides

Author

Gong, Haoning, primary, Hu, Xuzhi, additional, Liao, Mingrui, additional, Fa, Ke, additional, Ciumac, Daniela, additional, Clifton, Luke A., additional, Sani, Marc-Antoine, additional, King, Stephen M., additional, Maestro, Armando, additional, Separovic, Frances, additional, Waigh, Thomas A., additional, Xu, Hai, additional, McBain, Andrew J., additional, and Lu, Jian Ren, additional

Published
2021
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72. How do Self-Assembling Antimicrobial Lipopeptides Kill Bacteria?

Author

Gong, Haoning, primary, Sani, Marc-Antoine, additional, Hu, Xuzhi, additional, Fa, Ke, additional, Hart, Jack William, additional, Liao, Mingrui, additional, Hollowell, Peter, additional, Carter, Jessica, additional, Clifton, Luke A., additional, Campana, Mario, additional, Li, Peixun, additional, King, Stephen M., additional, Webster, John R. P., additional, Maestro, Armando, additional, Zhu, Shiying, additional, Separovic, Frances, additional, Waigh, Thomas A., additional, Xu, Hai, additional, McBain, Andrew J., additional, and Lu, Jian Ren, additional

Published
2020
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75. Suppressing the Phase Segregation with Potassium for Highly Efficient and Photostable Inverted Wide-Band Gap Halide Perovskite Solar Cells

Author

Liang, Jiwei, primary, Chen, Cong, additional, Hu, Xuzhi, additional, Chen, Zhiliang, additional, Zheng, Xiaolu, additional, Li, Jing, additional, Wang, Haibing, additional, Ye, Feihong, additional, Xiao, Meng, additional, Lu, Zhengyi, additional, Xu, Yuhao, additional, Zhang, Shunping, additional, Yu, Rui, additional, Tao, Chen, additional, and Fang, Guojia, additional

Published
2020
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78. Aggregated Amphiphilic Antimicrobial Peptides Embedded in Bacterial Membranes

Author

Gong, Haoning, primary, Liao, Mingrui, additional, Hu, Xuzhi, additional, Fa, Ke, additional, Phanphak, Sorasak, additional, Ciumac, Daniela, additional, Hollowell, Peter, additional, Shen, Kangcheng, additional, Clifton, Luke A., additional, Campana, Mario, additional, Webster, John R. P., additional, Fragneto, Giovanna, additional, Waigh, Thomas A., additional, McBain, Andrew J., additional, and Lu, Jian Ren, additional

Published
2020
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82. Manipulating the morphology of CdS/Sb2S3heterojunction using a Mg-doped tin oxide buffer layer for highly efficient solar cells

Author

Li, Jiashuai, Xiong, Liangbin, Hu, Xuzhi, Liang, Jiwei, Chen, Cong, Ye, Feihong, Li, Jing, Liu, Yongjie, Shao, Wenlong, Wang, Ti, Tao, Chen, and Fang, Guojia

Abstract

Mg-doped SnO2inserted between FTO and CdS manipulates the morphology of CdS/Sb2S3heterojunction and suppresses carrier recombination. The resultant solar cells deliver a remarkable champion efficiency of 6.31%.

Published
2022
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89. Coadsorption of a Monoclonal Antibody and Nonionic Surfactant at the SiO2/Water Interface

Author

Li, Zongyi, primary, Pan, Fang, additional, Li, Ruiheng, additional, Pambou, Elias, additional, Hu, Xuzhi, additional, Ruane, Sean, additional, Ciumac, Daniela, additional, Li, Peixun, additional, Welbourn, Rebecca J.L., additional, Webster, John R.P., additional, Bishop, Steven M., additional, Narwal, Rojaramani, additional, van der Walle, Christopher F., additional, and Lu, Jian Ren, additional

Published
2018
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93. Probing the relevance of synergistic lipid membrane disruption to the eye irritation of binary mixed nonionic surfactants.

Author

Wei F, Qi H, Li B, Cai R, Liao M, Li P, Zhan X, Zhu T, Xu H, Hu X, Lu JR, and Zhou F

Abstract

Nonionic surfactant aerosols play a crucial role in many industries, but they can cause acute irritation to users' eyes during spraying. This cytotoxic process is associated with corneal cell necrosis causing cell membrane disruption. Industrial grade surfactants are typically polydisperse mixtures described by their nominal chemical structure but how the polydispersity affects their interactions with cell membrane, remains largely unexplored. A better understanding could benefit product formulations to maximise their efficiency whilst minimising their toxicity to the users. In this study, poly-oxyethylene glycol monododecyl ethers (C 12 E 4 , C 12 E 23 ) were used to form ideal binary surfactant mixtures. The cytotoxicities of mono and polydispersed surfactants towards human corneal epithelial cells were examined, followed by a series of biophysical characterisations of interactions between surfactants and model cell membranes. Notably, to probe the journey of individual C 12 E 4 and C 12 E 23 surfactant molecules across the cell membrane from a binary surfactant mixture, "two-colour" neutron reflection measurements were achieved via Hydrogen/Deuterium substitution. The relative distributions of C 12 E 4 and C 12 E 23 across cell membranes and their nanostructural conformations revealed a synergistic membrane-lytic ability initiated by surfactant mixing, with the more hydrophobic C 12 E 4 exhibiting stronger membrane binding potency than the hydrophilic C 12 E 23 . The exact molar ratio of C 12 E 4 against C 12 E 23 in the mixture determined how the mixed surfactant interacted with the cell membrane, and how the process directly impacted cytotoxicity and eye irritation. Thus, the cytotoxicity of polydisperse surfactants is not the same as monodisperse surfactant of the same average structure. This work provides a useful basis for the assessment of surfactant mixing by balancing their efficiency and toxicity., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: The current work is part of collaborative research carried out at Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences and the University of Manchester, with input from ISIS neutron spallation source and China Spallation Neutron Source. The funding support has been formally acknowledged. The authors have no conflict of interest., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published
2024
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94. Suppressing Phase Segregation in Wide Bandgap Perovskites for Monolithic Perovskite/Organic Tandem Solar Cells with Reduced Voltage Loss.

Author

Wang C, Shao W, Liang J, Chen C, Hu X, Cui H, Liu C, Fang G, and Tao C

Abstract

Wide bandgap (WBG) perovskites through tuning iodine/bromine ratios are capable of merging with narrow bandgap organic bulk heterojunctions to construct tandem solar cells to overcome the Shockley-Queisser limitation. However, WBG perovskites readily suffer from light-induced halide ion migration, leading to detrimental phase segregation and hence severe open-circuit voltage (V OC ) loss. Here, to solve this issue, lead thiocyanate (Pb(SCN) 2 ) and 2-thiopheneethylammonium chloride (TEACl) are synergistically employed to passivate and stabilize WBG perovskites with 1.79 eV bandgap. It is demonstrated that the synergetic employment of Pb(SCN) 2 and TEACl suppresses light-induced phase segregation, passivates WBG perovskite defects, and reduces non-radiative recombination, hence alleviating V OC loss. As a result, optimized WBG perovskite solar cells (PSCs) are obtained with an impressive V OC of 1.26 V and power conversion efficiency (PCE) over 17.0%. Furthermore, the interconnection layer is optimized to minimize the V OC loss and construct two-terminal perovskite/organic tandem solar cells with a narrow bandgap organic blend bulk heterojunction of PM6:Y6 and achieve a champion PCE of 22.29% with a high V OC of 2.072 V. In addition, these tandem solar cells maintain 81% of their initial efficiency after 1000 h continuous tracking at the maximum power point (MPP) under 100 mW cm -2 white light illumination., (© 2022 Wiley-VCH GmbH.)

Published
2022
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95. Coadsorption of a Monoclonal Antibody and Nonionic Surfactant at the SiO 2 /Water Interface.

Author

Li Z, Pan F, Li R, Pambou E, Hu X, Ruane S, Ciumac D, Li P, Welbourn RJL, Webster JRP, Bishop SM, Narwal R, van der Walle CF, and Lu JR

Subjects
Adsorption, Humans, Hydrophobic and Hydrophilic Interactions, Antibodies, Monoclonal chemistry, Silicon Dioxide chemistry, Surface-Active Agents chemistry, Water chemistry
Abstract

During the formulation of therapeutic monoclonal antibodies (mAbs), nonionic surfactants are commonly added to attenuate structural rearrangement caused by adsorption/desorption at interfaces during processing, shipping, and storage. We examined the adsorption of a mAb (COE-3) at the SiO 2 /water interface in the presence of pentaethylene glycol monododecyl ether (C 12 E 5 ), polysorbate 80 (PS80-20EO), and a polysorbate 80 analogue with seven ethoxylates (PS80-7EO). Spectroscopic ellipsometry was used to follow COE-3 dynamic adsorption, and neutron reflection was used to determine interfacial structure and composition. Neither PS80-20EO nor C 12 E 5 had a notable affinity for COE-3 or the interface under the conditions studied and thus did not prevent COE-3 adsorption. In contrast, PS80-7EO did coadsorb but did not influence the dynamic process or the equilibrated amount of absorbed COE-3. Near equilibration, COE-3 underwent structural rearrangement and PS80-7EO started to bind the COE-3 interfacial layer and subsequently formed a well-defined surfactant bilayer via self-assembly. The resultant interfacial layer comprised an inner mAb layer of about 70 Å thickness and an outer surfactant layer of a further 70 Å, with distinct transitional regions across the mAb-surfactant and surfactant-bulk water boundaries. Once formed, such interfacial layers were very robust and worked to prevent further mAb adsorption, desorption, and structural rearrangement. Such robust interfacial layers could be anticipated to exist for formulated mAbs stored in type II glass vials; further research is required to understand the behavior of these layers for siliconized glass syringes.

Published
2018
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