Mechanoresponsive polymerized liquid metal networks CJ Thrasher, ZJ Farrell, NJ Morris, CL Willey, CE Tabor Advanced Materials 31 (40), 1903864, 2019 | 204 | 2019 |
Control of gallium oxide growth on liquid metal eutectic gallium/indium nanoparticles via thiolation ZJ Farrell, C Tabor Langmuir 34 (1), 234-240, 2018 | 201 | 2018 |
Oxidation of gallium-based liquid metal alloys by water MA Creighton, MC Yuen, MA Susner, Z Farrell, B Maruyama, CE Tabor Langmuir 36 (43), 12933-12941, 2020 | 80 | 2020 |
Chemically modifying the mechanical properties of core–shell liquid metal nanoparticles NJ Morris, ZJ Farrell, CE Tabor Nanoscale 11 (37), 17308-17318, 2019 | 60 | 2019 |
Silanized liquid-metal nanoparticles for responsive electronics ZJ Farrell, CJ Thrasher, AE Flynn, CE Tabor ACS Applied Nano Materials 3 (7), 6297-6303, 2020 | 42 | 2020 |
Route to universally tailorable room-temperature liquid metal colloids via phosphonic acid functionalization ZJ Farrell, N Reger, I Anderson, E Gawalt, C Tabor The Journal of Physical Chemistry C 122 (46), 26393-26400, 2018 | 31 | 2018 |
Straightforward, one-step synthesis of alkanethiol-capped silver nanoparticles from an aggregative model of growth Z Farrell, C Shelton, C Dunn, D Green Langmuir 29 (30), 9291-9300, 2013 | 30 | 2013 |
Gallium–indium nanoparticles as phase change material additives for tunable thermal fluids J Mingear, Z Farrell, D Hartl, C Tabor Nanoscale 13 (2), 730-738, 2021 | 21 | 2021 |
Development of experiment and theory to detect and predict ligand phase separation on silver nanoparticles Z Farrell, S Merz, J Seager, C Dunn, S Egorov, DL Green Angewandte Chemie 127 (22), 6579-6582, 2015 | 20 | 2015 |
Theoretical and experimental investigation of microphase separation in mixed thiol monolayers on silver nanoparticles SN Merz, ZJ Farrell, CJ Dunn, RJ Swanson, SA Egorov, DL Green ACS nano 10 (11), 9871-9878, 2016 | 17 | 2016 |
Textile‐Integrated Liquid Metal Electrodes for Electrophysiological Monitoring BM Li, BL Reese, K Ingram, ME Huddleston, M Jenkins, A Zaets, M Reuter, ... Advanced Healthcare Materials 11 (18), 2200745, 2022 | 13 | 2022 |
Compositional Design of Surface Oxides in Gallium–Indium Alloys ZJ Farrell, AR Jacob, VK Truong, A Elbourne, W Kong, L Hsiao, ... Chemistry of Materials 35 (3), 964-975, 2023 | 12 | 2023 |
Computational and Experimental Investigation of Janus-like Monolayers on Ultrasmall Noble Metal Nanoparticles SN Merz, ZJ Farrell, J Pearring, E Hoover, M Kester, SA Egorov, DL Green, ... ACS nano 12 (11), 11031-11040, 2018 | 7 | 2018 |
Core shell liquid metal encapsulates comprising multi-functional ligands and networks comprising same CJ Thrasher, CE Tabor, ZJ Farrell, NJ Morris US Patent 11,100,223, 2021 | 3 | 2021 |
Effects of particle size and oxide shell on variable stiffness performance of phase-changing materials TL Buckner, ZJ Farrell, AM Nasab, R Kramer-Bottiglio Journal of Composite Materials 57 (4), 619-631, 2023 | 2 | 2023 |
Articles comprising core shell liquid metal encapsulate networks and method to control alternating current signals and power CE Tabor, CJ Thrasher, AM Watson, NJ Morris, ZJ Farrell US Patent 11,406,956, 2022 | 2 | 2022 |
Substrates comprising a network comprising core shell liquid metal encapsulates comprising multi-functional ligands CJ Thrasher, CE Tabor, ZJ Farrell, NJ Morris US Patent 11,102,883, 2021 | 2 | 2021 |
Architected liquid metal networks and processes of making and using same CJ Thrasher, CE Tabor, ZJ Farrell, NJ Morris, MCS Yuen US Patent App. 16/671,750, 2020 | 2 | 2020 |
Stretchable Electronics: Mechanoresponsive Polymerized Liquid Metal Networks (Adv. Mater. 40/2019) C Thrasher, Z Farrell, N Morris, C Willey, C Tabor Advanced Materials 31 (40), 1970282, 2019 | 1 | 2019 |
Substrates comprising a network comprising core shell liquid metal encapsulates comprising multi-functional ligands CJ Thrasher, CE Tabor, ZJ Farrell, NJ Morris US Patent 11,856,690, 2023 | | 2023 |