Controlled Inkjetting of a Conductive Pattern of Silver Nanoparticles Based on the Coffee-Ring Effect

被引:218
|
作者
Zhang, Zhiliang [1 ,2 ]
Zhang, Xingye [1 ]
Xin, Zhiqing [1 ]
Deng, Mengmeng [1 ]
Wen, Yongqiang [1 ]
Song, Yanlin [1 ]
机构
[1] Chinese Acad Sci, Beijing Natl Lab Mol Sci, Key Lab Green Printing, Key Lab Organ Solids,Inst Chem, Beijing 100190, Peoples R China
[2] Shandong Polytech Univ, Res Ctr Anal & Test, Jinan 250353, Peoples R China
来源
ADVANCED MATERIALS | 2013年 / 25卷 / 46期
基金
中国国家自然科学基金;
关键词
silver nanoparticles; coffee-ring effect; wettability; surface patterning; inkjet printing; DROPLETS; EVAPORATION; DEPOSITION; FILMS; ELECTRONICS; RESOLUTION; FLOW;
D O I
10.1002/adma.201303278
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
Conductive patterns with line widths of 5-10 μm are successfully fabricated by utilizing the coffee-ring effect in inkjet printing, resulting in transmittance values of up to 91.2% in the visible to near-infrared region. This non-lithographic approach broadens the range of fabrication procedures that can be used to create various nanoparticle-based microstructures and electronic devices. © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.
引用
收藏
页码:6714 / 6718
页数:5
相关论文
共 50 条
  • [41] Assessment of coffee-ring effect on wool and cotton fabrics inkjet printed with herbal inks
    Thakker, Alka Madhukar
    Sun, Danmei
    JOURNAL OF THE TEXTILE INSTITUTE, 2024, 115 (08) : 1193 - 1206
  • [42] Rate-dependent interface capture beyond the coffee-ring effect
    Li, Yanan
    Yang, Qiang
    Li, Mingzhu
    Song, Yanlin
    SCIENTIFIC REPORTS, 2016, 6
  • [43] Evaporation Stains: Suppressing the Coffee-Ring Effect by Contact Angle Hysteresis
    Li, Yueh-Feng
    Sheng, Yu-Jane
    Tsao, Heng-Kwong
    LANGMUIR, 2013, 29 (25) : 7802 - 7811
  • [44] Phase-field modeling and computer simulation of the coffee-ring effect
    Junxiang Yang
    Hyundong Kim
    Chaeyoung Lee
    Sangkwon Kim
    Jian Wang
    Sungha Yoon
    Jintae Park
    Junseok Kim
    Theoretical and Computational Fluid Dynamics, 2020, 34 : 679 - 692
  • [45] Phase-field modeling and computer simulation of the coffee-ring effect
    Yang, Junxiang
    Kim, Hyundong
    Lee, Chaeyoung
    Kim, Sangkwon
    Wang, Jian
    Yoon, Sungha
    Park, Jintae
    Kim, Junseok
    THEORETICAL AND COMPUTATIONAL FLUID DYNAMICS, 2020, 34 (5-6) : 679 - 692
  • [46] Suppressing the coffee-ring effect of colloidal droplets by dispersed cellulose nanofibers
    Ooi, Yuto
    Hanasaki, Itsuo
    Mizumura, Daiki
    Matsuda, Yu
    SCIENCE AND TECHNOLOGY OF ADVANCED MATERIALS, 2017, 18 (01) : 316 - 324
  • [47] Reversing Coffee-Ring Effect by Laser-Induced Differential Evaporation
    Yen, Tony M.
    Fu, Xin
    Wei, Tao
    Nayak, Roshan U.
    Shi, Yuesong
    Lo, Yu-Hwa
    SCIENTIFIC REPORTS, 2018, 8
  • [48] Direct printing of graphene terahertz closed-ring resonator array from periodic single droplets via enhanced coffee-ring effect
    Lian, Hongcheng
    Qi, Lehua
    Luo, Jun
    Zhang, Ruirui
    Niu, Jianing
    CARBON, 2023, 215
  • [49] Redefining Molecular Amphipathicity in Reversing the "Coffee-Ring Effect": Implications for Single Base Mutation Detection
    Huang, Chi
    Wang, Jie
    Lv, Xiaobo
    Liu, Liu
    Liang, Ling
    Hu, Wei
    Luo, Changliang
    Wang, Fubing
    Yuan, Quan
    LANGMUIR, 2018, 34 (23) : 6777 - 6783
  • [50] A coffee-ring effect-based paper sensor chip for the determination of beta-lactoglobulin in foods via a smartphone
    Yang, Jingyi
    Zhang, Yong
    Wu, Lin
    Lu, Yang
    SENSORS AND ACTUATORS B-CHEMICAL, 2023, 374
12345