| Study of surface modification of nano-SiO2 with macromolecular coupling agent (LMPB-g-MAH) Y Tai, J Qian, Y Zhang, J Huang Chemical Engineering Journal 141 (1-3), 354-361, 2008 | 144 | 2008 |
| A highly sensitive, low-cost, wearable pressure sensor based on conductive hydrogel spheres Y Tai, M Mulle, IA Ventura, G Lubineau Nanoscale 7 (35), 14766-14773, 2015 | 143 | 2015 |
| Fabrication of paper-based conductive patterns for flexible electronics by direct-writing YL Tai, ZG Yang Journal of Materials Chemistry 21 (16), 5938-5943, 2011 | 135 | 2011 |
| Preparation, characterization and reaction mechanism of a novel silver-organic conductive ink Y Chang, DY Wang, YL Tai, ZG Yang Journal of Materials Chemistry 22 (48), 25296-25301, 2012 | 89 | 2012 |
| Double‐Twisted Conductive Smart Threads Comprising a Homogeneously and a Gradient‐Coated Thread for Multidimensional Flexible Pressure‐Sensing Devices Y Tai, G Lubineau Advanced Functional Materials 26 (23), 4078-4084, 2016 | 74 | 2016 |
| Light‐activated rapid‐response polyvinylidene‐fluoride‐based flexible films Y Tai, G Lubineau, Z Yang Advanced Materials 28 (23), 4665-4670, 2016 | 73 | 2016 |
| A facile approach to a silver conductive ink with high performance for macroelectronics Y Tao, Y Tao, B Wang, L Wang, Y Tai Nanoscale research letters 8, 1-6, 2013 | 63 | 2013 |
| Flexible pressure sensing film based on ultra-sensitive SWCNT/PDMS spheres for monitoring human pulse signals YL Tai, ZG Yang Journal of Materials Chemistry B 3 (27), 5436-5441, 2015 | 55 | 2015 |
| Preparation and characterization of Si3N4/SBR nanocomposites with high performance Y Tai, J Qian, J Miao, R Xia, Y Zhang, Z Yang Materials & Design 34, 522-527, 2012 | 50 | 2012 |
| Flexible, transparent, thickness-controllable SWCNT/PEDOT: PSS hybrid films based on coffee-ring lithography for functional noncontact sensing device YL Tai, ZG Yang Langmuir 31 (48), 13257-13264, 2015 | 47 | 2015 |
| Human‐Finger Electronics Based on Opposing Humidity‐Resistance Responses in Carbon Nanofilms Y Tai, G Lubineau Small, 2017,10.1002/smll.201603486, 2017 | 45 | 2017 |
| A promising approach to conductive patterns with high efficiency for flexible electronics YL Tai, ZG Yang, ZD Li Applied Surface Science 257 (16), 7096-7100, 2011 | 45 | 2011 |
| High-reproducibility, flexible conductive patterns fabricated with silver nanowire by drop or fit-to-flow method Y Tao, Y Tao, L Wang, B Wang, Z Yang, Y Tai Nanoscale research letters 8, 1-5, 2013 | 37 | 2013 |
| Toward Flexible Wireless Pressure‐Sensing Device via Ionic Hydrogel Microsphere for Continuously Mapping Human‐Skin Signals Y tai Zhenguo Yang advanced materials interfaces, 2017 | 36 | 2017 |
| Core/shell microstructure induced synergistic effect for efficient water-droplet formation and cloud-seeding application Y Tai, H Liang, A Zaki, N El Hadri, AM Abshaev, BM Huchunaev, ... Acs Nano 11 (12), 12318-12325, 2017 | 35 | 2017 |
| Preparation of stable aqueous conductive ink with silver nanoflakes and its application on paper‐based flexible electronics YL Tai, ZG Yang Surface and interface analysis 44 (5), 529-534, 2012 | 31 | 2012 |
| Facile and scalable preparation of solid silver nanoparticles (< 10 nm) for flexible electronics YL Tai, ZG Yang ACS Applied Materials & Interfaces 7 (31), 17104-17111, 2015 | 30 | 2015 |
| An effective way to stabilize silicon nitride nanoparticles dispersed in rubber matrix by a one-step process Y Tai, J Miao, J Qian, R Xia, Y Zhang Materials Chemistry and Physics 112 (2), 659-667, 2008 | 30 | 2008 |
| Heating-rate-triggered carbon-nanotube-based 3-dimensional conducting networks for a highly sensitive noncontact sensing device Y Tai, G Lubineau Scientific Reports 6 (1), 19632, 2016 | 27 | 2016 |
| Green approach to prepare silver nanoink with potentially high conductivity for printed electronics YL Tai, YX Wang, ZG Yang, ZQ Chai Surface and interface analysis 43 (12), 1480-1485, 2011 | 24 | 2011 |
