Access the full text.
Sign up today, get DeepDyve free for 14 days.
Yumeng Xin, Hao Peng, Jun Xu, Jiuyang Zhang (2019)
Ultrauniform Embedded Liquid Metal in Sulfur Polymers for Recyclable, Conductive, and Self‐Healable MaterialsAdvanced Functional Materials, 29
M. Yim, Yi Li, K. Moon, K. Paik, C. Wong (2008)
Review of Recent Advances in Electrically Conductive Adhesive Materials and Technologies in Electronic PackagingJournal of Adhesion Science and Technology, 22
Guolin Yun, Shiyang Tang, Shuaishuai Sun, Dan Yuan, Qianbin Zhao, L. Deng, Sheng Yan, H. Du, M. Dickey, Weihua Li (2019)
Liquid metal-filled magnetorheological elastomer with positive piezoconductivityNature Communications, 10
Xiankai Li, Mingjie Li, Lu Zong, Xiaochen Wu, Jun You, Peikang Du, Chaoxu Li (2018)
Liquid Metal Droplets Wrapped with Polysaccharide Microgel as Biocompatible Aqueous Ink for Flexible Conductive DevicesAdvanced Functional Materials, 28
M. Dickey (2017)
Stretchable and Soft Electronics using Liquid MetalsAdvanced Materials, 29
Navid Kazem, T. Hellebrekers, C. Majidi (2017)
Soft Multifunctional Composites and Emulsions with Liquid MetalsAdvanced Materials, 29
Suqing Liang, Yaoyao Li, Yuzhen Chen, Jinbin Yang, Taipeng Zhu, Deyong Zhu, Chuanxin He, Yizhen Liu, Stephan Handschuh‐Wang, Xuechang Zhou (2017)
Liquid metal sponges for mechanically durable, all-soft, electrical conductorsJournal of Materials Chemistry C, 5
(2017)
Global Electrically Conductive Adhesives Market Forecasts up to 2023—Research and Markets, Business Wire
Lifei Zhu, Yuzhen Chen, Wenhui Shang, Stephan Handschuh‐Wang, Xiaohu Zhou, Tiansheng Gan, Qixing Wu, Yizhen Liu, Xuechang Zhou (2019)
Anisotropic liquid metal–elastomer compositesJournal of Materials Chemistry C
Xiankai Li, Mingjie Li, Jie Xu, Jun You, Zhiqin Yang, Chaoxu Li (2019)
Evaporation-induced sintering of liquid metal droplets with biological nanofibrils for flexible conductivity and responsive actuationNature Communications, 10
Shengfu Mei, Yunxia Gao, Z. Deng, Jing Liu (2014)
Thermally Conductive and Highly Electrically Resistive Grease Through Homogeneously Dispersing Liquid Metal Droplets Inside Methyl Silicone OilJournal of Electronic Packaging, 136
Hongzhang Wang, Bo Yuan, Shuting Liang, Rui Guo, Wei Rao, Xuelin Wang, Hao-Jhen Chang, Yujie Ding, Jing Liu, Lei Wang (2017)
PLUS-M: a Porous Liquid-metal enabled Ubiquitous Soft MaterialMaterials horizons, 5
Hongzhang Wang, Youyou Yao, Zhizhu He, Wei Rao, Liang Hu, Sen Chen, Ju Lin, Jianye Gao, Pengju Zhang, Xuyang Sun, Xiangjiang Wang, Yuntao Cui, Qian Wang, S. Dong, Guozhen Chen, Jing Liu (2019)
A Highly Stretchable Liquid Metal Polymer as Reversible Transitional Insulator and ConductorAdvanced Materials, 31
Hua-yue Wu, Jian Liu, Xiaoxin Wu, M. Ge, Yanli Wang, Zhang Guangxue, Jianzhong Jiang (2006)
High conductivity of isotropic conductive adhesives filled with silver nanowiresInternational Journal of Adhesion and Adhesives, 26
Tiansheng Gan, Wenhui Shang, Stephan Handschuh‐Wang, Xuechang Zhou (2019)
Light-Induced Shape Morphing of Liquid Metal Nanodroplets Enabled by Polydopamine Coating.Small, 15 9
Minjoon Park, Hyungyeon Cha, Yoonji Lee, Jaehyung Hong, Sung Kim, Jaephil Cho (2017)
Postpatterned Electrodes for Flexible Node‐Type Lithium‐Ion BatteriesAdvanced Materials, 29
A. Heeger, A. MacDiarmid, H. Shirakawa (2007)
Electrically Conductive Adhesives
Hao Peng, Yumeng Xin, Jun Xu, Huaizhi Liu, Jiuyang Zhang (2019)
Ultra-stretchable hydrogels with reactive liquid metals as asymmetric force-sensorsMaterials Horizons
B. Blaiszik, S. Kramer, Martha Grady, David Mcilroy, J. Moore, N. Sottos, S. White (2012)
Autonomic Restoration of Electrical ConductivityAdvanced Materials, 24
W. Reus, M. Thuo, N. Shapiro, C. Nijhuis, G. Whitesides (2012)
The SAM, not the electrodes, dominates charge transport in metal-monolayer//Ga2O3/gallium-indium eutectic junctions.ACS nano, 6 6
S. Jeong, Francisco Cruz, Si Chen, L. Gravier, Johan Liu, Zhigang Wu, K. Hjort, Shi-Li Zhang, Zhi-Bin Zhang (2017)
Stretchable Thermoelectric Generators Metallized with Liquid Alloy.ACS applied materials & interfaces, 9 18
Yue Lu, Quanyin Hu, Yiliang Lin, Dennis Pacardo, Chao Wang, Wujin Sun, F. Ligler, M. Dickey, Zhen Gu (2015)
Transformable liquid-metal nanomedicineNature Communications, 6
A. Fassler, C. Majidi (2015)
Liquid‐Phase Metal Inclusions for a Conductive Polymer CompositeAdvanced Materials, 27
Qian Wang, Yang Yu, Jing Liu (2018)
Preparations, Characteristics and Applications of the Functional Liquid Metal MaterialsAdvanced Engineering Materials, 20
B. Ellis (1992)
Chemistry and technology of epoxy resins
Ilse Meerbeek, Benjamin Murray, Jae Kim, Sanlin Robinson, Perry Zou, M. Silberstein, R. Shepherd (2016)
Morphing Metal and Elastomer Bicontinuous Foams for Reversible Stiffness, Shape Memory, and Self‐Healing Soft MachinesAdvanced Materials, 28
Eric Markvicka, Ravi Tutika, Michael Bartlett, C. Majidi (2019)
Soft Electronic Skin for Multi‐Site Damage Detection and LocalizationAdvanced Functional Materials, 29
Michael Bartlett, A. Fassler, Navid Kazem, Eric Markvicka, P. Mandal, C. Majidi (2016)
Stretchable, High‐k Dielectric Elastomers through Liquid‐Metal InclusionsAdvanced Materials, 28
Long Teng, S. Ye, Stephan Handschuh‐Wang, Xiaohu Zhou, Tiansheng Gan, Xuechang Zhou (2019)
Liquid Metal‐Based Transient Circuits for Flexible and Recyclable ElectronicsAdvanced Functional Materials, 29
Riku Takahashi, T. Sun, Yoshiyuki Saruwatari, T. Kurokawa, Daniel King, J. Gong (2018)
Creating Stiff, Tough, and Functional Hydrogel Composites with Low‐Melting‐Point AlloysAdvanced Materials, 30
J. Eagan, Jun Xu, R. Girolamo, Christopher Thurber, C. Macosko, Anne LaPointe, F. Bates, G. Coates (2017)
Combining polyethylene and polypropylene: Enhanced performance with PE/iPP multiblock polymersScience, 355
Lu‐yu Zhou, Jianzhong Fu, Qing Gao, P. Zhao, Yong He (2019)
All‐Printed Flexible and Stretchable Electronics with Pressing or Freezing Activatable Liquid‐Metal–Silicone InksAdvanced Functional Materials, 30
J. Licari, D. Swanson (2003)
Adhesives Technology for Electronic Applications: Materials, Processing, Reliability
Eric Markvicka, Michael Bartlett, Xiaonan Huang, C. Majidi (2018)
An autonomously electrically self-healing liquid metal–elastomer composite for robust soft-matter robotics and electronicsNature Materials, 17
S. Jeong, Si Chen, J. Huo, E. Gamstedt, Johan Liu, Shi-Li Zhang, Zhi-Bin Zhang, K. Hjort, Zhigang Wu (2015)
Mechanically Stretchable and Electrically Insulating Thermal Elastomer Composite by Liquid Alloy Droplet EmbedmentScientific Reports, 5
R. Chiechi, E. Weiss, M. Dickey, G. Whitesides (2008)
Eutectic gallium-indium (EGaIn): a moldable liquid metal for electrical characterization of self-assembled monolayers.Angewandte Chemie, 47 1
Attributed by the unique mechanical and electrical properties, functional blends of liquid metals (LMs) and polymers have received lots of attention. The deformation of LM‐polymer materials under extreme force to create electrical conductivity has built many electronic applications. However, the fundamental understanding of the relationship among polymer networks, LM deformation, and electrical conductivity remains too opaque to have a general principle for further advanced LM‐polymer electronics. This work discovered that the energy dissipation of polymer matrix plays a determinative role in controlling the electrical behaviors of LM‐polymers. The relationship among polymer network, deformation, and external pressure is investigated to design many unique electronic applications not shown in prevalent LM elastomers. The human pressure successfully disrupts high energy dissipated (HED) polymer networks and cracks LM fillers to provide anisotropic conductivity along pressure direction while insulated in planar directions. Meanwhile, under flexural forces, the HED LM‐polymer film can be also conductive along the maximum curvature of films but insulated in intact areas. Different folded and printed circuits are customized and prepared from the HED LM‐polymers. In addition, a new generation of anisotropic electrical adhesives is successfully fabricated from HED LM‐polymer resins, which shows advantages over current commercially available products.
Advanced Materials Technologies – Wiley
Published: May 1, 2020
Keywords: ; ;
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.