个人概况 研究领域 教学与课程 科研项目 科技成果 论文与著作 荣誉及奖励
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邓天松

职称: 研究员

毕业院校:北京大学

邮件: dengts@hdu.edu.cn

办公地点: 四教110

职务:

研究方向: 纳米光学材料与器件
最新更新

        长期从事与纳米材料、器件与智能检测相关的基础研究工作,包括异形金纳米颗粒合成及自组装、金纳米复合材料的等离激元增强光催化和传感特性研究、生物医学智能检测等。发表SCI论文50余篇,包括Advanced MaterialsNano Letters、Journal of Colloid and Interface Sciencetop期刊论文;H-index19,被引用1300余次。担任《Nanomaterials》客座编辑,担任Small、Journal of Colloid and Interface Science、Materials HorizonSmall Methods、Advanced Optical Materials多个国际学术期刊独立审稿人,共审稿70余篇。授权中国发明专利16。主持国家自然科学基金1项浙江省自然科学基金1项;主持和参与多项横向科研项目。参加美国材料协会年会、美国SPIE光子学会议、德国物理学年会等国际学术会议10余次,并在2015年美国材料协会春季年会上获得最佳报告奖。

        课题组有良好的学术氛围,欢迎对我们研究方向感兴趣的研究生和本科生加入研究队伍。课题组将为每位学生提供良好科研平台和一对一定期指导,对发表高水平科研成果进行奖励。2020级学生已获得国家奖学金1人,每个学生均有多篇SCI论文发表。团队还提供去国内外知名高校(北京大学、美国芝加哥大学、荷兰乌特勒支大学、德国马普研究所)交流深造的机会。

教育经历

20009- 20047月,北京大学,电子信息科学与技术,学士

20049- 20107月,北京大学,物理电子学,博士

工作经历

20109-20128月,德国马普研究所,博士后

20129-20158月,荷兰乌特勒支大学,博士后

201510-20195月,美国芝加哥大学,研究专员

20196-至今,杭州电子科技大学,电子信息学院,研究员(特聘教授

社会职务
研究领域

关键词:纳米光学材料与器件表面等离激元材料、纳米传感与智能检测等离激元光催化

        我们的研究工作聚焦于纳米材料、光子学与纳米技术的交叉领域。课题组的主要目标是开发高性能的无机纳米材料,探索其在纳米光学器件、柔性传感、生物医学检测及能源转化中的应用。我们致力于从基础材料合成出发,通过精准调控纳米颗粒的形貌与组装行为,深入理解表面等离激元增强效应的物理化学机制。

目前,课题组主要研究方向包括:

1. 表面等离激元材料的制备

贵金属纳米材料(如金、银、铜)的独特性质源于其传导电子在光激发下的集体振荡,即表面等离激元共振。我们专注于开发高效的合成策略(如低浓度表面活性剂体系、双表面活性剂法),实现金纳米棒、纳米双锥及其核壳/空心结构的高收率、高均一性制备。通过精确控制纳米材料的身材成分,我们为构建下一代纳米光学材料与器件提供核心物质基础。


1 不同类型金纳米(复合)结构及透射电镜图


代表性论文

1.   L. Y. Liu, Y. Q. Dou, M. Bransen, A. van Blaaderen, T. S. Deng*, X. Zhao, D. Yu, Synthesis of gold nanorod@Pd(Pt)-Cu2O dendritic nanocomposites for plasmon-enhanced photocatalysis, J. Colloid Interface Sci., 2026, 716, 140337.

2.   E. J. Zhang, T. S. Deng*, Z. Chen, L. Y. Liu, G. L. Wu, Y. C. Cheng, J. F. Gao, K. P. Wang, J. Liu, Seed-mediated synthesis of gold nanobipyramids at low CTAB concentration using binary surfactants, Part. Part. Syst. Char., 2024, 41, 2400190.

3.   M. Z. Wei, T. S. Deng*, Q. Zhang, Z. Cheng, S. Li, Seed-mediated synthesis of gold nanorods at low concentration of CTAB, ACS Omega, 2021, 6, 9188-9195.

2. 纳米光学材料的多尺度组装

孤立的纳米颗粒类似于“纳米原子”,通过自组装可以将它们排列成一维等离激元链、二维有序薄膜、三维超晶体或超颗粒簇。我们利用界面化学修饰与溶剂诱导驱动,实现纳米颗粒在宏观尺度上的有序排列。这些组装体不仅产生了强烈的等离激元耦合效应,还赋予了材料宽带吸收、相位转移及可折叠等新型物理特性,为研制柔性纳米光学器件和高性能超材料开辟了新途径。

 

 2 一维链状、二维平面与三维簇状金纳米结构组装示意图及其电镜图


代表性论文

1.   L. Chen, X. H. Zhang, H. Ito, T. S. Deng*, CTAB–4,4′-bipyridine interface-mediated self-assembly of gold nanobipyramids into stable plasmonic chains, J. Mater. Sci., 2026, 61, 11237-11249.

2.   J. F. Gao, J. Liu, G. L. Wu, K. P. Wang, Y. Gao, T. S. Deng*, Size-tunable gold nanosphere superlattices with enhanced SERS performance, Colloids Surf. A, 2025, 726, 137761.

3.   X. Li, X. Chen, J. Liu, X. Zhao, J. Liu, Z. Cheng, T. S. Deng*, Superparticles of gold nanorods with controllable bandwidth and spectral shape for lipophilic SERS, Nanoscale, 2023, 15, 12270-12279.

3. 纳米传感与智能检测

等离激元纳米结构表面可产生强局域电磁场,从而显著增强分子的拉曼信号(SERS效应)。本方向通过设计核壳结构、空心结构及超颗粒体系,构建高灵敏纳米传感平台,实现对复杂环境污染物及生物分子的高选择性检测。


3 表面增强拉曼散射(SERS)机理示意图


代表性论文

1.   J. F. Gao, J. Liu, G. L. Wu, K. P. Wang, Y. Gao, T. S. Deng*, Size-tunable gold nanosphere superlattices with enhanced SERS performance, Colloids Surf. A, 2025, 726, 137761.

2.   Z. M. Shen, J. Liu*, K. P. Wang, X. H. Zang, L. Chen, Z. Zhou, T. S. Deng*, Synthesis of gold nanorodAuAg hollow shell nanostructures with enhanced refractive index sensitivity and SERS activity, Part. Part. Syst. Char., 2025, 42, e00110.

3.   J. E. S. van der Hoeven*, T. S. Deng*, W. Albrecht, L. A. Olthof, M. A. van Huis, P. E. de Jongh, A. van Blaaderen*, Structural control over bimetallic core−shell nanorods for surface-enhanced Raman spectroscopy, ACS Omega, 2021, 6, 7034-7046.

4. 等离激元光催化

等离激元纳米材料在光激发下可产生高能热电子与强局域电场,从而显著提升界面处的化学反应效率。本研究方向致力于开发跨尺度的等离激元催化体系,不仅涵盖传统的贵金属-半导体异质结(如Au-CuO/TiO),更深入探索了多金属合金核壳结构(如Au@PdPt, AuNBPs@AgPt)以及具有高比表面积的空心或树枝状多组分复合体系。通过精准设计组分分布与形貌,利用等离激元诱导的热电子注入、近场增强及光热协同效应,实现可见光驱动的高效光催化反应,在环境有机污染物降解与洁净能源转化领域展现出广阔的应用前景。

 

4 AuNR–Cu2OAuNR@Pd–Cu2OAuNR@Pt–Cu2O纳米结构催化还原甲基橙的机理示意图


代表性论文

1.   L. Y. Liu, Y. Q. Dou, M. Bransen, A. van Blaaderen, T. S. Deng*, X. Zhao, D. Yu, Synthesis of gold nanorod@Pd(Pt)-Cu2O dendritic nanocomposites for plasmon-enhanced photocatalysis, J. Colloid Interface Sci., 2026, 716, 140337.

2.   E. J. Zhang, T. S. Deng*, Y. C. Cheng, L. Y. Liu, J. F. Gao, J. Wen, X. Zhao, J. Liu, Gold nanobipyramids coated with silver-platinum alloy shells for plasmonically enhanced photocatalytic degradation of methyl orange, ACS Appl. Nano Mater., 2024, 7, 14596-14608.

3.   Y. Q. Dou, Q. Zhang, T. S. Deng*, Z. Cheng, X. Zhao, Deposition of Pd-Pt alloy zigzag shell over Au nanorods for boosted catalysis and thermo-photo-catalysis, J. Mater. Sci., 2024, 59, 2302-2314.
教学与课程

《通信电路与系统》,《纳米科技的应用》
横向科研
纵向科研

1. 球型受限空间中金纳米粒子的自组装及其光学特性研究,国家自然科学基金青年项目(61905056),2020/01-2022/12,已结题,主持。

2. 单个贵金属纳米结构的局域表面等离激元共振效应研究,浙江省自然科学基金项目(LY24F050008),2024/01-2026/12,在研,主持。
专利成果

(1) 邓天松陈希知群一种吸收带可调的色弱矫正眼镜的制备方法, 2025-12-12, ZL202210678231.2

(2) 邓天松;卫鸣璋;陈希;张敏;李勋;周涛;顾伊杰;李仕琦;程知群,一种亲油金纳米棒制备方法,2025-1-10ZL202111545492.9

(3) 邓天松;窦云奇;张敏;胡鑫;李仕琦;程知群,一种在金纳米棒两端包覆二氧化硅的方法,2025-1-10ZL202111658412.0

(4) 邓天松;陈希;卫鸣璋;李仕琦;顾伊杰;周涛;程知群,一种棒骨状金纳米棒的合成方法,2024-11-22, ZL202111401927.2

(5) 邓天松;李勋;卫鸣璋;胡鑫;李仕琦;程知群,一种包覆薄二氧化硅金纳米棒自组装的方法,2024-11-22, ZL202111658329.3

(6) 邓天松李勋卫鸣璋胡鑫李仕琦程知群一种球形金纳米棒自组装超级粒子的制备方法2024-10-22ZL202111654775.7

(7) 邓天松陈希窦云奇李仕琦顾伊杰程知群一种以邻苯二酚为还原剂的金纳米棒的合成方法2024-10-1ZL202111392003.0

(8) 邓天松陈希; 李勋李仕琦; 顾伊杰程知群一种单分散性好的金纳米棒合成方法, 2024-5-24, ZL202111410901.4

(9) 邓天松; 张棋; 卫鸣璋; 顾伊杰; 程知群一种金-铂双金属结构材料的合成方法, 2023-8-11, ZL202011637855.7

(10) 邓天松; 陈希; 程知群一种具有宽带可调吸收特性的金纳米棒及其制备方法, 2023-7-14, ZL202210700193.6

(11) 邓天松; 陈希; 程知群一种金纳米棒薄膜及其合成方法, 2023-4-28, ZL202210700334.4

(12) 邓天松; 张棋; 卫鸣璋; 陈希; 顾伊杰; 程知群一种中空的金--铂三金属材料及其合成方法, 2023-6-6, ZL202110657361.3

(13) 邓天松; 卫鸣璋; 张棋; 顾伊杰; 程知群一种低表面活性剂浓度下金纳米棒材料的制备方法, 2023-4-14, ZL202011603131.0

(14) 邓天松; 张棋; 卫鸣璋; 陈希; 顾伊杰; 程知群一种不对称的金---银多层复合材料及其合成方法, 2023-1-15, ZL202110657362.8

(15) 邓天松; 张棋; 卫鸣璋; 顾伊杰; 程知群一种介孔二氧化硅包覆金纳米棒表面生长银复合材料的制备方法, 2022-11-15, ZL202011631700.2

(16) 邓天松; 卫鸣璋; 张棋; 顾伊杰; 程知群, 一种金纳米棒表面生长可调厚度二氧化硅材料的制备方法, 2022-11-15, ZL202011629357.8
软件成果
论文

学术论文(入职杭电后

27) L. Y. Liu, Y. Q. Dou, M. Bransen, A. van Blaaderen, T. S. Deng*, X. Zhao, D. Yu, Synthesis of gold nanorod@Pd(Pt)-Cu2O dendritic nanocomposites for plasmon-enhanced photocatalysis, J. Colloid Interface Sci., 2026, 716, 140337.  (*通讯作者)Deng2026 JCIS - AuNR-Pd(Pt)-Cu2O for Plasmon-Enhanced Photocatalysis.pdf

26) L. Chen, X. H. Zhang, H. Ito, T. S. Deng*, CTAB–4,4′-bipyridine interface-mediated self-assembly of gold nanobipyramids into stable plasmonic chains, J. Mater. Sci., 2026, 61, 11237-11249. (*通讯作者)Deng2026 JMaterSci - AuNBPs plasmonic chains.pdf

25)  K. P. Wang, J. Liu*, X. Chen, G. L. Wu, E. J. Zhang, T. S. Deng*Two-step seed-mediated growth for the reproducible synthesis of high quality gold nanorods, J. Chem. Sci.2026138, 15(*通讯作者)Deng2026 JChemSci - Two-Step AuNRs Synthesis.pdf

24) Z. M. Shen, J. Liu*, Q. Zhang, E. J. Zhang, X. Zhao, Y. Gao*, Z. Zhou, T. S. Deng*, Gold nanorods coated with palladium-platinum alloy shell superstructures for enhanced plasmon-driven photocatalysis, Part. Part. Syst. Char.2025, 42e00121. (*通讯作者)Deng2025 PPSC - Au-PdPt Superstructures for Photocatalysis.pdf

23)  Z. M. Shen, J. Liu*, K. P. Wang, X. H. Zang, L. Chen, Z. Zhou, T. S. Deng*, Synthesis of gold nanorod@AuAg hollow shell nanostructures with enhanced refractive index sensitivity and SERS activity, Part. Part. Syst. Char.2025, 42, e00110. (*通讯作者)Deng2025 PPSC - AuNR-AuAg Hollow Shell .pdf

22)  J. F. Gao, J. Liu*, G. L. Wu, K. P. Wang, Y. Gao*, T. S. Deng*, Size-tunable gold nanosphere superlattices with enhanced SERS performance, Colloids Surf. A, 2025, 726, 137761. (*通讯作者) (times cited: 2)Deng2025 Colloids Surfaces A - Gold Nanosphere Superlattices.pdf

21)  Y. C. Cheng, Y. Q. Dou, T. S. Deng*, Performance enhancement of trimetallic nanoparticles in photocatalysis through chemical etching, J. Nanoprt. Res., 2025, 27, 177. (*通讯作者(times cited: 2)Deng2025 J Nanoprt Res Au@AgPt-E.pdf

20)  Y. C. Cheng, T. S. Deng*, Au@Pd nanorods with a suitable shell thickness of titanium dioxide can improve its catalytic performances, AIP Adv., 2025, 15, 065008. (*通讯作者(times cited: 1)Deng2025 AIP Adv - Au@Pd@TiO2 for photocatalysis.pdf

19)  G. L. Wu, T. S. Deng*, K. P. Wang, E. J. Zhang, L. Y. Liu, Y. C. Cheng, J. F. Gao, J. Liu, Synthesis of lipophilic gold nanorod superparticles and their size‑dependent SERS performances, J. Nanoprt. Res., 2025, 27, 19. (*通讯作者)Deng2025 J Nanopart Res - Gold Nanorods Superparticels.pdf

18) K. P. Wang, T. S. Deng*, E. J. Zhang, J. F. Gao, J. Liu, Controlled etching of gold nanorods within mesoporous silica shells at mild conditionsPart. Part. Syst. Char.202542, 2400144. (*通讯作者)

17) E. J. Zhang, T. S. Deng*, Z. Chen, L. Y. Liu, G. L. Wu, Y. C. Cheng, J. F. Gao, K. P. Wang, J. Liu, Seed-mediated synthesis of gold nanobipyramids at low CTAB concentration using binary surfactants, Part. Part. Syst. Char., 2024, 41, 2400190. (*通讯作者(times cited: 2)Deng2024 PPSC-Gold Nanobipyramids.pdf

16) E. J. Zhang, T. S. Deng*, Y. C. Cheng, L. Y. Liu, J. F. Gao, J. Wen, X. Zhao, J. Liu, Gold nanobipyramids coated with silver-platinum alloy shells for plasmonically enhanced photocatalytic degradation of methyl orange, ACS Appl. Nano Mater., 2024, 7, 14596-14608. (*通讯作者(times cited: 11)Deng2024 ACS-ANM - AuNBPs@AgPt Alloys for Photocatalysis.pdf

15)  M. Zhang, J. Liu*, X. Li, X. Zhao, Z. Cheng, T. S. Deng*, Versatile approach to self-assembly of surface modified nanoparticles into SERS-active nanoclusters, Part. Part. Syst. Char., 2024, 41, 2400034. (*通讯作者(times cited: 1)Deng2024 Particles - Self‐Assembly of Suparparticles.pdf

14) Y. Q. Dou, Q. Zhang, T. S. Deng*, Z. Cheng, X. Zhao, Deposition of Pd-Pt alloy zigzag shell over Au nanorods for boosted catalysis and thermo-photo-catalysis, J. Mater. Sci., 2024, 59, 2302-2314. (*通讯作者(times cited: 5)Deng2024 J Mater Sci - Au@PdPt.pdf

13)  X. Chen, J. Liu*, X. Li, Z. Cheng, T. S. Deng*, Predictable and adjustable broadband gold nanorods for photothermal effects and foldable performances, Nanotechnology, 2024, 35, 115701. (*通讯作者)Deng2024 Nanotechnology - Broadband GNRs Films.pdf

12) M. Zhang, T. S. Deng*, Z. Cheng, Ethanol as a ‘catalyst’ for effective phase transfer and self-assembly of gold nanorods, ChemistrySelect, 2023, 8, e202301065. (*通讯作(times cited: 3)Deng2023 ChemistrySelect - Phase Transfer of AuNRs.pdf

11)  X. Li, X. Chen, J. Liu, X. Zhao, J. Liu, Z. Cheng, T. S. Deng*, Superparticles of gold nanorods with controllable bandwidth and spectral shape for lipophilic SERS, Nanoscale, 2023, 15, 12270-12279. (*通讯作者(times cited: 8)Deng2023 Nanoscale - AuNRs Broadband Superparticles.pdf

10) Y. Q. Dou, T. S. Deng*, Q. Zhang, X. Zhao, J. Liu, Z. Cheng, A study of size-controlled Au@Cu2O nanocomposite for highly improved methyl orange catalytic performances, J. Mater. Sci., 2023, 58, 7583-7593. (*通讯作者(times cited: 7)Deng2023 J Mater Sci - Au@Cu2O for photocatalysis.pdf

9)  Q. Zhang, T. S. Deng*, Y. Q. Dou, M. Z. Wei, S. Li, J. Liu, Z. Cheng, Trimetallic nanostructures of silver-platinum hollow alloy shell on gold nanorods for plasmon- mediated photocatalysis, ACS Appl. Nano Mater., 2022, 5, 17048-17058. (*通讯作者(times cited: 9)Deng2022 ACS Applied Nano Materials.pdf

8) M. Z. Wei, T. S. Deng*, Q. Zhang, X. Chen, Z. Cheng, S. Li, Y. J. Gu, New rule and growth model for the synthesis of gold nanorods with binary surfactant CTAB and NaOL, AIP Adv., 2022, 12, 085019. (*通讯作者(times cited: 3)Deng2022 AIP Advances.pdf

7) X. Chen, T. S. Deng*, M. Zhou, Z. Dong, Z. Cheng, Mixed-phase TiO2 with oxygen vacancies for enhanced visible light photocatalysis performance, Nano, 2022, 17, 2250025. (*通讯作者(times cited: 3)Deng2022 Nano.pdf

6) Y. Yifat, J. Parker, T. S. Deng, S. K. Gray, S. A. Rice, N. F. Scherer, Facile measurement of the rotation of a single optically trapped nanoparticle using the diagonal ratio of a quadrant photo-diode, ACS Photonics, 2021, 8, 3162-3172. (times cited: 4)2021 ACS Photonics - Yuval.pdf

5) Q. Zhang, T. S. Deng*, M. Z. Wei, X. Chen, Z. Cheng, S. Li, Y. J. Gu, Symmetric and asymmetric overgrowth of Ag shell onto gold nanorods assisted by Pt pre-deposition, RSC Adv., 2021, 11, 34516-34524. (*通讯作者(times cited: 9)Deng2021 RSC Advances.pdf

4) W. Albrecht, E. A. Irmak, T. Altantzis, A. Pedrazo-Tardajos, A. Skorikov, T. S. Deng, J. E.S. van der Hoeven, A. van Blaaderen, S. Van Aert, S. Bals, 3D atomic-scale dynamics of laser-light-induced restructuring of nanoparticles unraveled by electron tomography, Adv. Mater. 2021, 2100972. (times cited: 21)2021 AM - Wiebke 3D atomic resolution by laser induced reconstructing.pdf

3) M. Z. Wei, T. S. Deng*, Q. Zhang, Z. Cheng, S. Li, Seed-mediated synthesis of gold nanorods at low concentration of CTAB, ACS Omega, 2021, 6, 9188-9195. (*通讯作者(times cited: 124)Deng2021 ACS Omega.pdf

2) J. E. S. van der Hoeven$*, T. S. Deng$*, W. Albrecht, L. A. Olthof, M. A. van Huis, P. E. de Jongh, A. van Blaaderen*, Structural control over bimetallic core−shell nanorods for surface-enhanced Raman spectroscopy, ACS Omega, 2021, 6, 7034-7046. ($共同一作, *通讯作者(times cited: 43)2021 ACS Omega Jessi&Deng.pdf

1) T. S. Deng$, J. Parker$, Y. Hirai, N. Shepherd, H. Yabu, N. F. Scherer, Designing “metamolecules” for photonic function: reduced backscattering, Phys. Status Solidi B2020, 2000169. ($共同一作(times cited: 8)Deng2020 PSSB.pdf


学术论文(入职杭电前,部分代表性成果10/24

1. J. Li, T. S. Deng, X. Liu, J. A. Dolan, N. F. Scherer, P. F. Nealey, Hierarchical assembly of plasmonic nanoparticle heterodimer arrays with tunable sub5 nm nanogaps, Nano Lett., 2019, 19, 4314-4320. (times cited: 37)2019 NL- Hierarchical Assembly of Plasmonic Nanoparticle Heterodimer Arrays with Tunable Sub‑5 nm Nanogaps.pdf

2. T. S. Deng$, J. Parker$, Y. Yifat, N. Shepherd, N. F. Scherer, Dark plasmon modes in symmetric gold nanoparticle dimers illuminated by focused cylindrical vector beams, J. Phys. Chem. C, 2018, 122, 27662-27672. ($共同一作(times cited: 64)Deng2018 JPCC.pdf

3. U. Manna$, J. –H. Lee$, T. S. Deng$, J. Parker$, N. Shepherd, Y. Weizmann, N. F. Scherer, Selective induction of optical magnetism, Nano Lett., 2017, 17, 7196-7206. ($共同一作(times cited: 46)Deng2017 NanoLett - Selective Induction of Optical Magnetism.pdf

4. W. Albrecht, J. E. S. van der Hoeven, T. S. Deng, P. E. de Jongh, A. van Blaaderen, Fully alloyed metal nanorods with highly tunable properties, Nanoscale, 2017, 9, 2845-2851. (times cited: 49)2017 Nanoscale - Wiebke - Fully alloyed metal nanorods with highly tunable properties.pdf

5. W. Albrecht*, T. S. Deng, B. Goris, M. A. van Huis, S. Bals, A. van Blaaderen*, Single particle deformation and analysis of silica-coated gold nanorods before and after femtosecond laser pulse excitation, Nano Lett., 2016, 16, 1818-1825. (*通讯作者) (times cited: 81)2016 NL Albrecht.pdf

6. T. S. Deng*, J. E. S. van der Hoeven, A. O. Yalcin, H. W. Zandbergen, M. A. van Huis, A. van Blaaderen*, Oxidative etching and metal overgrowth of gold nanorods within mesoporous silica shells, Chem. Mater., 2015, 27, 7196-7203. (*通讯作者(times cited: 57)Deng2015 ChemMater.pdf

7. T. S. Deng*, H. J. Bongard, F. Marlow*, A one-step method to coat polystyrene particles with an organo-silica shell and their functionalization, Mater. Chem. Phys., 2015, 162, 548-554. (*通讯作者(times cited: 18)Deng2015 Mater. Chem. Phys..pdf

8. T. S. Deng, F. Marlow, Synthesis of monodisperse polystyrene@vinyl-SiO2 core–shell particles and hollow SiO2 spheres, Chem. Mater., 2012, 24, 536-542. (times cited: 125)Deng2012 Chem. Mater..pdf

9. T. S. Deng, J. Y. Zhang, K. T. Zhu, Q. F. Zhang, J. L. Wu, Highly monodisperse vinyl functionalized silica spheres and their self-assembled three-dimensional colloidal photonic crystals, Colloids Surf. A, 2010, 356, 104-111. (times cited: 38)Deng2010 Colloids Surf. A.pdf

10. T. S. Deng, Q. F. Zhang, J. Y. Zhang, X. Shen, K. T. Zhu, J. L. Wu, One-step synthesis of highly monodisperse hybrid silica spheres in aqueous solution, J. Colloid Interface Sci., 2009, 329, 292-299. (times cited: 131)Deng2009 J. Colloids Interface Sci..pdf
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