代表论文:
14. Xiaojing Wang, Yiming Xu, Siyuan Xiang, Shengyang Tao*, Wendong Liu*. Hydrogel-Assisted Robust Supraparticles Evolved from Droplet Evaporation. ACS. Nano. 2024, Accepted, DOI:10.1021/acsnano.4c15025. IF= 15.8, JCR: Q1.
13. Xiaojing Wang, Yuechang Lian, Siyuan Xiang, Shengyang Tao*, Michael Kappl, Wendong Liu*. Droplet Evaporation on Super Liquid-Repellent Surfaces: A Controllable Approach for Supraparticle Fabrication. Adv. Colloid Interface Sci. 2024, 334 (Dec), 103305. IF= 16.0, JCR: Q1.
Abstract:Supraparticles are agglomerates of nano- and/or microparticles with sizes ranging from tens to hundreds of microns, making them more accessible for handling and recovery than the building blocks. Supraparticles not only inherit the properties and functions of primary particles but also exhibit characteristics such as high porosity, large specific surface area, and improved functionalities, which can be attributed to the synergism, coupling, and co-localization among the constituents. Therefore, supraparticles hold promising applications in catalysis, drug delivery, sensing, etc. Among the various synthesizing strategies, evaporating droplets on a liquid-repellent surface is proposed as an effective approach to fabricate supraparticles with unique structural features and functions. The boundary conditions of such droplet-confinement methods significantly drive the formation of supraparticles by reducing or avoiding the use of solvents or processing liquids, which further accelerates the development and utilization of supraparticles. This paper presents an overview of recent developments in the fabrication of supraparticles by evaporating droplets on liquid-repellent surfaces. The review focuses on the evaporation processes on lubricant and superhydrophobic surfaces, structural regulation, and applications of supraparticles. Finally, an outlook on the future directions of evaporation on liquid-repellent surfaces mediated supraparticle fabrication is presented.
12. Wendong Liu,* Xiaojing Wang, Siyuan Xiang, Yuechang Lian, Shengyang Tao.* Stretchable Superhydrophobic Surfaces: From Basic Fabricaiton Strategies to Applications. Processes 2024, 12, 124. IF= 2.8, JCR: Q2.
Abstract: Superhydrophobic surfaces find extensive applications in various fields, including self-cleaning, liquid manipulation, anti-icing, and water harvesting. To achieve superhydrophobicity, the surfaces are designed with hierarchical nano- and/or microscale protrusions. These structures result in a static contact angle above 150° and a sliding/rolling-off angle below 10° when water droplets deposit on the surface. The combination of hierarchical structures and low-surface energy materials contributes to this unique liquid-repellent property. In addition to liquid repellency, the durability of these surfaces is crucial for practical applications, which has prompted the exploration of stretchable superhydrophobic surfaces as a viable solution. The flexibility of these surfaces means that they are effectively safeguarded against mechanical damage and can withstand daily wear and tear. Over the last decade, considerable research has been dedicated to developing stretchable superhydrophobic surfaces to expand their potential applications. This review provides an overview of stretchable superhydrophobic surfaces, specifically emphasizing current processing strategies and their prospective applications. Additionally, we present a forward-looking perspective on future fabrication methods to create robust superhydrophobic surfaces, further enhancing their practicality and versatility.
11. Wendong Liu, Michael Kappl,* Werner Steffen, Hans-Jürgen Butt. Controlling Supraparticle Shape and Structure by Tuning Colloidal Interactions. J. Colloid Interface Sci. 2022, 607, 1661-1670. IF= 9.4, JCR: Q1.
Abstract:Hypothesis:Assembly of colloids in drying colloidal suspensions on superhydrophobic surface is influenced by the colloidal interactions, which determine the shape and interior structure of the assembled supraparticle. The introduction of salt (electrolyte) into the assembly system is expected to influence the colloid interactions and packing during the evaporation process. Hence, both the outer shape and internal structure of supraparticles should be controlled by varying salt concentrations. Experiments:Suspensions of electrostatically stabilized polystyrene particles with specified salt concentrations were chosen as model systems to conduct the evaporation on a superhydrophobic surface. A systematic study was performed by regulating the concentration and valency of salt. The morphology and interior of supraparticles were carefully characterized with electron scanning microscopy, while the colloidal interaction was established using colloidal probe atomic force microscopy. Findings:Supraparticles displayed a spherical-to-nonspherical shape change due to the addition of salts. The extent of crystallization depended on salt concentration. These changes in shape and structure were correlated with salt-dependent single colloid interaction forces, which were not previously investigated in detail in radially symmetric evaporation geometry. Our findings are crucial for understanding assembly behavior during the drying process and offer guidance for preparing complex supraparticles to meet specific applications requirement.
10. Siyuan Xiang, and Wendong Liu*. Self-Healing Superhydrophobic Surfaces: Healing Principles and Applications. Adv. Mater. Interfaces 2021, 8(12), 2100247. IF=4.3, JCR: Q2.
Abstract:Superhydrophobic surfaces have already been applied in anti-fouling, water-oil separation, liquid transportation, etc. Surfaces can be defined as superhydrophobic surfaces once they can support a water droplet with its spherical shape maintained and accompanied by an apparent contact angle larger than 150° and a rolling-off angle below 10°. Such water repellent property is achieved by the synergetic action of hierarchical structures and the low-surface energy of the substances constructing the surface. Structures with high aspect ratio always perform good superhydrophobicity. However, they are usually with poor mechanical stability. Since durability is one of the essential factors for practical use, exploiting robust superhydrophobic surfaces has attracted tremendous interest. During the past decade, great effort has been made in developing self-healing superhydrophobic surfaces to improve the potential practice and broaden the application fields. An overview of the recent development of self-healing superhydrophobic surfaces is provided in this review. The focus here is particularly on the fabrication process based on specific healing mechanisms and possible applications. Finally, an outlook on future fabrication techniques for durable superhydrophobic surfaces is presented.
09. Wendong Liu,* Siyuan Xiang, Xueyao Liu, and Bai Yang*. Underwater Superoleophobic Surface Based on Silica Hierarchical Cylinder Arrays with a Low Aspect Ratio. ACS Nano 2020, 14(7), 9166-9175. IF=15.8, JCR: Q1.
Abstract:A superantiwetting surface based on low-aspect-ratio hierarchical cylinder arrays (HCAs) was successfully obtained on a silica substrate by colloidal lithography with photolithography. Colloidal lithography is a technique involving transfer of a pattern to a substrate by etching or exposure to a radiation source through a mask composed of a packed colloidal crystal, while photolithography is utilized by which a pattern is transferred photographically to a photoresist-coated substrate, and the substrate is subsequently etched. The surface provides an alternative approach to apply aligned micro-nano integrated structures with a relatively low aspect ratio in superantiwetting. The obtained HCAs successfully integrated micro- and nanoscale structures into one system, and the physical structure of the HCAs can be tuned by modulating the fabrication approach. Using a postmodification process, the underwater–oil wetting behavior of cylinder-array based surfaces can be easily modulated from the superoleophobic state (an oil contact angle (OCA) of 161°) to oleophilic state (an OCA of 19°). Moreover, the underwater–oil wettability can be reversibly transformed from the superoleophobic state (an OCA of approximately 153°) into the oleophilic state (an OCA of approximately 31°) by grafting stimuli-responsive polymer (PNIPAAm) brushes onto this specific hierarchical structure. Due to the temperature-responsive property, modifying the surface with PNIPAAm provides a possibility to control the oil wettability (repellent or sticky) by temperature, which will benefit the use of HCAs in oil–water separation and other application fields.
08. Wendong Liu, Michael Kappl,* and Hans-Jürgen Butt. Tuning the Porosity of Supraparticles. ACS Nano 2019, 13 (12), 13949-13956. IF=15.8, JCR: Q1.
Abstract:Supraparticles consisting of nano- or microparticles have potential applications as, for example, photonic crystals, drug carriers, or heterogeneous catalysts. To avoid the use of solvent or processing liquid, one can make supraparticles by evaporating droplets of aqueous suspensions from super-liquid-repellent surfaces. Herein, a method to adjust the porosity of supraparticles is described; a high porosity is desired, for example, in catalysis. To prepare highly porous TiO2 supraparticles, polymer nanoparticles are co-dispersed in the suspension. Supraparticles are formed through evaporation of aqueous suspension droplets on superamphiphobic surfaces followed by calcination of the sacrificial polymer particles. The increase of porosity of up to 92% resulted in enhanced photocatalytic activity while maintaining sufficient mechanical stability.
07. Wendong Liu,# Jiarul Midya,# Michael Kappl, Hans-Jürgen Butt,* and Arash Nikoubashman. Segregation in Drying Binary Colloidal Droplets. ACS Nano 2019, 13(5), 4972-4979. IF=15.8, JCR: Q1.
Abstract:When a colloidal suspension droplet evaporates from a solid surface, it leaves a characteristic deposit in the contact region. These deposits are common and important for many applications in printing, coating, or washing. By the use of superamphiphobic surfaces as a substrate, the contact area can be reduced so that evaporation is almost radially symmetric. While drying, the droplets maintain a nearly perfect spherical shape. Here, we exploit this phenomenon to fabricate supraparticles from bidisperse colloidal aqueous suspensions. The supraparticles have a core–shell morphology. The outer region is predominantly occupied by small colloids, forming a close-packed crystalline structure. Toward the center, the number of large colloids increases and they are packed amorphously. The extent of this stratification decreases with decreasing the evaporation rate. Complementary simulations indicate that evaporation leads to a local increase in density, which, in turn, exerts stronger inward forces on the larger colloids. A comparison between experiments and simulations suggest that hydrodynamic interactions between the suspended colloids reduce the extent of stratification. Our findings are relevant for the fabrication of supraparticles for applications in the fields of chromatography, catalysis, drug delivery, photonics, and a better understanding of spray-drying.
06. Wendong Liu, and Bai Yang*. Patterned Surfaces for Biological Applications: A New Platform Using Two Dimensional Structures As Biomaterials. Chinese Chem. Lett. 2017, 28: 675–690. IF=9.4, JCR: Q1.
Abstract:With the highly interdisciplinary of research and great development of microfabrication techniques, patterned surfaces have attracted great attention of researchers since they possess specific regularity and orderness of structures. In recent years, series of two dimensional patterned structures have been successfully fabricated, and widely used in anti-reflection, anti-fogging, self-cleaning, and sensing, etc. In the meantime, patterned structures have been gradually used in biologically relative fields such as biomaterials, aiming to deepen the perception of organism and understand the vital movements of human body. In this review, we provide a brief introduction on current status of techniques for two dimensional patterns fabrication, the applications of patterned surfaces in biologically related fields, and give out a prospective on the development of these patterned surfaces in the future.
05. Wendong Liu, Xueyao Liu, Siyuan Xiang, Yixin Chen, Liping Fang, and Bai Yang*. Functional Interface Based on Silicon Artificial Chamfer Nanocylinder Arrays (CNCAs) with Underwater Superoleophobicity and Anisotropic Properties. Nano Res. 2016, 9, 3141-3151. IF=9.5, JCR: Q1.
Abstract:A functional interface based on silicon chamfer nanocylinder arrays (CNCAs) was successfully fabricated by carrying out secondary etching of silicon nanopillar arrays via a facile inclined etching method. The structure of the novel CNCAs was finely modulated by varying the nanopillar array structure and the etching conditions. The underwater oil wetting behavior of this CNCAs-based interface can be easily modulated from superoleophilic (oil contact angle (OCA) of ~8.13°) state to superoleophobic (OCA of ~163.79°) state by modifying the surface using different substances. Moreover, a reversible transformation of underwater oil wetting behavior from superoleophobic (OCA of ~155.67°) state to oleophilic (OCA of ~31.27°) state was achieved by grafting a temperature-responsive polymer onto this specific asymmetric structure. The functional interface exhibited isotropic wetting behavior under certain oleophilic conditions. Chemically heterogeneous structures, obtained via asymmetry modification of CNCAs, exhibited amphiphobic properties while maintaining their anisotropic wetting ability.
04. Wendong Liu, Xueyao Liu, Peng Ge, Liping Fang, Siyuan Xiang, Xiaohuan Zhao, Huaizhong Shen,and Bai Yang*. Hierarchical-Multiplex DNA Patterns Mediated by Polymer Brush Nanocone Arrays That Possess Potential Application for Specific DNASensing. ACS Appl. Mater. Interfaces 2015, 7, 24760−24771. IF=8.3, JCR: Q1.
Abstract:This paper provides a facile and cost-efficient method to prepare single-strand DNA (ssDNA) nanocone arrays and hierarchical DNA patterns that were mediated by poly(2-hydroxyethyl methacrylate) (PHEMA) brush. The PHEMA brush nanocone arrays with different morphology and period were fabricated via colloidal lithography. The hierarchical structure was prepared through the combination of colloidal lithography and traditional photolithography. The DNA patterns were easily achieved via grafting the amino group modified ssDNA onto the side chain of polymer brush, and the anchored DNA maintained their reactivity. The as-prepared ssDNA nanocone arrays can be applied for target DNA sensing with the detection limit reaching 1.65 nM. Besides, with the help of introducing microfluidic ideology, the hierarchical-multiplex DNA patterns on the same substrate could be easily achieved with each kind of pattern possessing one kind of ssDNA, which are promising surfaces for the preparation of rapid, visible, and multiplex DNA sensors.
03. Wendong Liu, Xueyao Liu, Jiaozi Fangteng, Shuli Wang, Liping Fang, Huaizhong Shen, Siyuan Xiang, Hongchen Sun and Bai Yang*. Bioinspired Polyethylene Terephthalate Nanocone Arrays with Underwater Superoleophobicity and Anti-bioadhesion Properties. Nanoscale 2014, 6, 13845. IF=5.8, JCR: Q1.
02. Wendong Liu, Yunfeng Li, Tieqiang Wang, Daowei Li, Liping Fang, Shoujun Zhu,Huaizhong Shen, Junhu Zhang, Hongchen Sun, and Bai Yang*. Elliptical Polymer Brush Ring Array Mediated Protein Patterning and Cell Adhesion on Patterned Protein Surfaces. ACS Appl. Mater. Interfaces 2013, 5, 12587−12593. IF=8.3, JCR: Q1.
Abstract:This paper presents a novel method to fabricate elliptical ring arrays of proteins. The protein arrays are prepared by covalently grafting proteins to the polymer brush ring arrays which are prepared by the techniques combining colloidal lithography dewetting and surface initiated atom-transfer radical polymerization (SI-ATRP). Through this method, the parameters of protein patterns, such as height, wall thickness, periods, and distances between two elliptical rings, can be finely regulated. In addition, the sample which contains the elliptical protein ring arrays can be prepared over a large area up to 1 cm2, and the protein on the ring maintains its biological activity. The as-prepared ring and elliptical ring arrays (ERAs) of fibronectin can promote cell adhesion and may have an active effect on the formation of the actin cytoskeleton.
01. Liu Wendong, Li Yunfeng and Yang Bai*. Fabrication and Applications of The Protein Patterns. Sci. China Chem. 2013, 56 (8), 1087-1100. IF=10.4, JCR: Q1.
Abstract:Protein has been widely used for fabricating patterned structures since it is one of the most important macromolecules in living organisms, and protein patterns possess potential applications in many fields such as medical diagnosis, tissue engineering, biosensors, and medical screening. At present, there are two fashions to fabricate protein patterns: one is grafting the protein to the microstructure which is prepared by micro-fabrication techniques; the other one is achieving the patterned protein structures directly. Here we provide an overview on current status of the fabrication techniques and the applications of the protein patterns, and then give an outlook on the development of the fabrication techniques and the prospective applications of the protein patterns in future research.
专著章节:
1. Chapter 5: 'Photonic Crystals Fabricated via Facile Methods and Their Applications'
contribute to the book 'Photonic Materials for Sensing, Biosensing and Display Devices', Springer International Publishing Switzerland 2016, M. Serpe et al. (eds.), Springer Series in Materials Science 229,
Wendong Liu, Xueyao Liu, and Bai Yang*
Volume 229 of the series Springer Series in Materials Science pp 101-158. Chapter DOI 10.1007/978-3-319-24990-2_5.
2. Chapter 6: 'Silicon/Polymer Composite Nanopost Arrays'
contribute to the book 'Silicon Nanomaterials Sourcebook: Arrays, Functional Materials, Industrial Nanosilicon', CRC Press Taylor & Francis Group 6000 Broken Sound Parkway NW, Suite 300 Boca Raton, FL 33487-2742 © 2017 by Taylor & Francis Group, LLC. Klaus D. Sattler et al. (eds.),
Xueyao Liu, Wendong Liu, and Bai Yang*
Volume Two, 1st edition. Pp 153-166.
3. Chapter 2: 'Self-Recovery Superhydrophobic Surfaces'
contribute to the book 'Materials with Extreme Wetting Properties: Methods and Emerging Industrial Applications', Springer International Publishing Switzerland 2021, Hosseini, Majid & Karapanagiotis, Ioannis (eds.), 1st edition, pp 39-61.
Wendong Liu,* Michael Kappl, Hans-Jürgen Butt
Chapter DOI 10.1007/978-3-030-59565-4_2.
4. Chapter 19: 'Stretchable Superhydrophobic Coatings'
contribute to the book 'Advances in Superhydrophobic Coatings', Royal Society of Chemistry 2023, Viswanathan S Saji (eds.), 1st edition, pp 428-451.
Xiaojing Wang, Siyuan Xiang, Wendong Liu,* Shengyang Tao
Chapter DOI 10.1039/9781837670031-00428.
署名论文发表情况:
2024
1. Jihong Ouyang, Wenbo Yang,* Zhaoyan Guo, Fujun Li, Wendong Liu, Pengfei Guo, Yumeng Zhou, Dali Gao,* Lijing Zhang, and Shengyang Tao*. Modular Cascade of Flow Reactors: Continuous Flow Synthesis of Water-Insoluble Diazo Dyes in Aqueous System. ChemSusChem 2024, DOI: 10.1002/cssc.202400413.
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2023
1. Shi Feng, Cunliang Pan, Hongfei Ye, Wendong Liu, Wenbo Yang, Yingdi Lv, Shengyang Tao*. Magnetic Non-Spherical Particles Inducing Vortices in Microchannel for Effective Mixing. Small, 2023, 2207383.
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2022
2. Xiaolong Zheng, Wendong Liu, Shi Feng, Yongxian Yu, Yingdi Lv*, Shengyang Tao*. Microcapsules-supported Pd catalysts with ultralow ionic residues, Colloid. Surface. A, 2022, 639, 128343.
1. Xiaoteng Zhou, Jie Liu,* Wendong Liu, Werner Steffen, Hans-Jürgen Butt. Fabrication of Stretchable Superamphiphobic Surfaces with Deformation-Induced Rearrangeabel Structures. Adv.Mater., 2022, 34, 2107901.
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2021
2. Jianxiong Han, Chaoming Xie, Yun-Shuai Huang, Manfred Wagner, Wendong Liu, Xiaolong Zeng, Jiahui Liu, Shijie Sun, Kaloian Koynov, Hans-Jürgen Butt, Si Wu*. Ru-Se Coordination: A New Dynamic Bond for Visible-Light-Responsive Materials.J. Am. Chem. Soc., 2021, 143(32), 12736-12744.
1. Xin Zhao, Andreas Best, Wendong Liu, Kaloian Koynov,* Hans-Jürgen Butt, and Clarissa Schönecker. Irregular, Nanostructured Superhzdrophobic Surfaces: Local Wetting and Slippage Monitored by Fluorescence Correlation Spectroscopy. Phys. Rev. Fluids, 2021, 6(5), 054004.
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2019
5. Lijun Ye, Fei Chen, Jie Liu, Aiting Gao, Gunnar Kircher, Wendong Liu, Michael Kappl, Seraphine Wegner, Hans-Jürgen Butt, and Werner Steffen*. Responsive Ionogel Surface with Renewable Antibiofouling Properties. Macromol. Rapid Commun., 2019, 1900395.
4. Siyuan Xiang, Qingnan Meng, Kai Zhang,* Yue Gu, Wendong Liu, and Bai Yang. Facile Synthesis of ZnO-Au Nanopetals and Their Application for Biomolecule Determinations. Chem. Res. Chinese Universities, 2019, 35(5), 924―928.
3. Xueyao Liu, Wendong Liu, and Bai Yang*. Highly Ordered 3D-Silver Nanoring Arrays (3D-AgNRAs) for Refractometric Sensing. J. Mater. Chem. C, 2019, 7, 7681-7691.
2. Xueyao Liu, Wendong Liu, and Bai Yang*. Deep-Elliptical-Silver-Nanowell Arrays (d-EAgNWAs) Fabricated by Stretchable Imprinting Combining Colloidal Lithography: A Highly Sensitive Plasmonic Sensing Platform. Nano Res., 2019, 12, 845-853.
1. Peihong Xue, Wendong Liu, Zhongyi Gu, Xingchi Chen, Jingjie Nan, Junhu Zhang*, Hongchen Sun, Zhanchen Cui, and Bai Yang. Graded Protein/PEG Nanopattern Arrays: Well-Defined Gradient Biomaterials to Induce Basic Cellular Behaviors. ACS Appl. Mater. Interfaces, 2019, 11 (1), 1595–1603.
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2018
1. Liping Fang, Xueyao Liu, Siyuan Xiang, Wendong Liu, Huaizhong Shen, Zibo Li, Kai Zhang*, Wei Song*, and Bai Yang. Large-Scale Au Nanoparticle Cluster Arrays with Tunable Particle Numbers Evolved from Colloidal Lithography. Nanotechnology, 2018, 29, 405301.
2. Peng Ge, Jianglei Zhang, Yongshun Liu, Shuli Wang, Wendong Liu, Nianzuo Yu, Yuxin Wu, Junhu Zhang,* and Bai Yang. Smart Anisotropic Wetting Surfaces with Reversed PH-Responsive Wetting Directions. Adv. Funct. Mater., 2018, 28, 1802001.
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2017
1. Peng Ge, Shuli Wang, Wendong Liu, Tieqiang Wang, Nianzuo Yu, Peihong Xue, Hongxu Chen, Huaizhong Shen, Junhu Zhang,* and Bai Yang. Anisotropic Wetting of Water on Patterned Asymmetric Nanostructure Arrays. Adv. Mater. Interfaces 2017, 4, 1700034.
2. Huaizhong Shen, Yuxin Wu, Wenjing Wang, Hongyang Su, Wendong Liu, Junhu Zhang, Kai Zhang,* and Bai Yang. Au Nanorods-Sensitized 1DPC for Visible Detection of NIR Light. J. Mater. Chem. C 2017, 5, 2942-2950.
3. Peng Ge, Shuli Wang, Yongshun Liu, Wendong Liu, Nianzuo Yu, Jianglei Zhang, Huaizhong Shen, Junhu Zhang*, and Bai Yang. Autonomous Control of Fluids in A Wide Surface Tension Range in Microfluidics. Langmuir 2017, 33 (29), 7248–7255.
4. Siyuan Xiang, Hu-Jun Qian, Yixin Chen, Kai Zhang*, Yanhong Shi, Wendong Liu, Haizhu Sun, Hongchen Sun, and Bai Yang. Chelation Competition Induced Polymerization (CCIP): A Binding Energy Based Strategy for Nonspherical Polymer Nanocontainers’ Fabrication. Chem. Mater. 2017, 29 (15), 6536–6543.
5. Xueyao Liu, Wendong Liu, Liping Fang, Shunsheng Ye, Huaizhong Shen, and Bai Yang*. Highly Sensitive Deep-Silver-Nanowell Arrays (d-AgNWAs) for Refractometric Sensing. Nano Res. 2017, 10(3): 908–921.
6. Nianzuo Yu, Shuli Wang, Yongshun Liu, Peihong Xue, Peng Ge, Jingjie Nan, Shunsheng Ye, Wendong Liu, Junhu Zhang*, and Bai Yang. Thermal-Responsive Anisotropic Wetting Microstructures for Manipulation of Fluids in Microfluidics. Langmuir 2017, 33 (2), 494–502.
7. Peng Ge, Shuli Wang, Wendong Liu, Tieqiang Wang, Nianzuo Yu, Shunsheng Ye, Huaizhong Shen, Yuxin Wu, Junhu Zhang*, and Bai Yang. Unidirectional Wetting of Liquids on “Janus” Nanostructure Arrays Under Various Media. Langmuir 2017, 33 (9), 2177–2184.
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2016
1. Siyuan Xiang, Dandan Wang, Kai Zhang,* Wendong Liu, Ce Wu, Qingnan Meng, Hongchen Sun, and Bai Yang. Chelation Competition Induced Polymerization (CCIP): Construction of Integrated Hollow Polydopamine Nanocontainers With Tailorable Functionalities. Chem. Commun. 2016,52, 10155-10158.
2. Shuli Wang, Nianzuo Yu, Tieqiang Wang, Peng Ge, Shunsheng Ye, Peihong Xue, Wendong Liu, Huaizhong Shen, Junhu Zhang*, and Bai Yang. Morphology-Patterned Anisotropic Wetting Surface for Fluid Control and Gas–Liquid Separation in Microfluidics. ACS Appl. Mater. Interfaces 2016, 8 (20), 13094–13103.
3. Yuxin Wu, Huaizhong Shen, Shunsheng Ye, Dong Yao, Wendong Liu, Junhu Zhang, Kai Zhang*, and Bai Yang. Multifunctional Reversible Fluorescent Controller Based On A One-Dimensional Photonic Crystal. ACS Appl. Mater. Interfaces 2016, 8 (42), 28844–28852.
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2015
1. Hongxu Chen, Tieqiang Wang, Huaizhong Shen, Wendong Liu, Shuli Wang, Kun Liu, Junhu Zhang,* Bai Yang. Ag Nanoparticle/Polymer Composite Barcode Nanorods. Nano Res. 2015, 8(9): 2871–2880.
2. Yuanyuan Zhan, Jianqiang Zhao, Wendong Liu, Bai Yang, Jia Wei, and Yanlei Yu*. Biomimetic Submicroarrayed Cross-Linked Liquid Crystal Polymer Films with Different Wettability via Colloidal Lithography. ACS Appl. Mater. Interfaces 2015, 7 (45), 25522–25528.
3. Huaizhong Shen, Yuxin Wu, Liping Fang, Shunsheng Ye, Zhaoyi Wang, Wendong Liu, Zhongkai Cheng, Junhu Zhang, Zhanhua Wang*, and Bai Yang*. From 1D to 3D: A New Route to Fabricate Tridimensional Structures via Photo-Generation of Silver Networks. RSC Adv. 2015, 5, 28633-28642.
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2014
1. Daowei Li, Haizhu Sun, Liming Jiang, Kai Zhang, Wendong Liu, Yang Zhu, Jiaozi Fangteng, Ce Shi, Liang Zhao, Hongchen Sun*, and Bai Yang. Enhanced Biocompatibility of PLGA Nanofibers with Gelatin/Nano-Hydroxyapatite Bone Biomimetics Incorporation. ACS Appl. Mater. Interfaces 2014, 6 (12), 9402–9410.
2. Liping Fang, Yunfeng Li, Zhaolai Chen, Wendong Liu, Junhu Zhang, Siyuan Xiang, Huaizhong Shen, Zibo Li, and Bai Yang*. Tunable Polymer Brush/Au NPs hybrid Plasmonic Arrays Based on Host–Guest Interaction. ACS Appl. Mater. Interfaces 2014, 6 (22), 19951–19957.
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2013
1. Yunfeng Li, Junhu Zhang, Wendong Liu, Daowei Li, Liping Fang, Hongchen Sun, and Bai Yang*. Hierarchical Polymer Brush Nanoarrays: A Versatile Way to Prepare Multiscale Patterns of Proteins. ACS Appl. Mater. Interfaces 2013, 5 (6), 2126–2132.
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2012
1. Yunfeng Li, Junhu Zhang, Liping Fang, Liming Jiang, Wendong Liu, Tieqiang Wang, Liying Cui, Hongchen Sun, and Bai Yang*. Polymer Brush Nanopatterns with Controllable Features for Protein Pattern Applications. J. Mater. Chem. 2012,22, 25116-25122.
荣誉奖励:
1.博士研究生国家奖学金(2016,教育部);
2.吉林大学优秀研究生、研究生一等优秀奖学金、学术业绩奖学金等。
3.2023年大连理工大学教学质量优良奖。
4.2024年中国石油教育学会石油高等教育教学成果奖(本科) 一等奖(排名:15)
