| Magnetorheological fluid composites synthesized for helicopter landing gear applications LA Powell, W Hu, NM Wereley Journal of intelligent material systems and structures 24 (9), 1043-1048, 2013 | 58 | 2013 |
| Experimental characterization of thermal conductance switching in magnetorheological fluids G Cha, YS Ju, LA Ahuré, NM Wereley Journal of Applied Physics 107 (9), 2010 | 47 | 2010 |
| Scaling temperature dependent rheology of magnetorheological fluids SG Sherman, LA Powell, AC Becnel, NM Wereley Journal of Applied Physics 117 (17), 2015 | 38 | 2015 |
| Nonlinear modeling of adaptive magnetorheological landing gear dampers under impact conditions LAA Powell, YT Choi, W Hu, NM Wereley Smart Materials and Structures 25 (11), 115011, 2016 | 33 | 2016 |
| Magnetorheological fluids employing substitution of nonmagnetic for magnetic particles to increase yield stress LA Powell, NM Wereley, J Ulicny IEEE Transactions on Magnetics 48 (11), 3764-3767, 2012 | 27 | 2012 |
| High strain rate mechanical characterization of carbon fiber reinforced polymer composites using digital image correlations LA Powell, WE Luecke, M Merzkirch, K Avery, T Foecke SAE International Journal of Materials and Manufacturing 10 (2), 138-146, 2017 | 15 | 2017 |
| Rheological characterization of a magnetorheological ferrofluid using iron nitride nanoparticles NMW LM Armijo, LA Ahuré-Powell Journal of Applied Physics 117 (17), 2015 | 11 | 2015 |
| Behavior of Magnetorheological Fluids Employing Carrier Fluids Certified for Landing Gear Use L Ahure´, NM Wereley Smart Materials, Adaptive Structures and Intelligent Systems 43314, 849-857, 2008 | 11 | 2008 |
| Magnetorheological fluids and applications to adaptive landing gear for a lightweight helicopter LA Ahure-Powell University of Maryland, College Park, 2014 | 9 | 2014 |
| Measurements of Mode I Interlaminar Properties of Carbon Fiber Reinforced Polymers Using Digital Image Correlation M Merzkirch, L Ahure Powell, T Foecke Key Engineering Materials 742 (1662-9795), 652-659, 2017 | 6 | 2017 |
| Adaptive magnetorheological landing gear dampers employing passive valves to maximize applicable sink rate range LA Powell, YT Choi, W Hu, NM Wereley, TS Birchette, AO Bolukbasi, ... Proceedings of the American Helicopter Society 69th Annual Forum Technology …, 2013 | 6 | 2013 |
| Snappy: A New Automated Testing Machine for Monitoring the Break Evolution Process during Single Fiber Fragmentation Test LAA Powell, RJ Sheridan, S Yucel, B Yucel, E Rust, SR Kalidindi, ... Experimental Techniques 47 (5), 1073-1084, 2023 | 3 | 2023 |
| A non-intrusive fluorescent pattern for internal microscale strain measurements using digital image correlation LA Ahure Powell, WD Mulhearn, S Chen, SJ Stranick, JW Gilman, ... Experimental Techniques 47 (6), 1183-1199, 2023 | 1 | 2023 |
| Magnetorheological Fluids and Applications to Adaptive Landing Gear for a Lightweight Helicopter LA Powell | 1 | 2014 |
| An autonomous design algorithm to experimentally realize three-dimensionally isotropic auxetic network structures without compromising density HMJJJP Meng Shen, Marcos A. Reyes-Martinez, Louise Ahure Powell, Mark A ... npj computational materials 10 (113), 2024 | | 2024 |
| Snappy: A New Automated Testing Machine for Monitoring the Break Evolution Process during Single Fiber Fragmentation Test (Aug, 10.1007/s-40799-022-00611-3, 2022) LA Powell, RJ Sheridan, S Yucel, B Yucel, E Rust, SR Kalidindi, ... EXPERIMENTAL TECHNIQUES 47 (2), 549-549, 2023 | | 2023 |
| Correction to: Snappy: A New Automated Testing Machine for Monitoring the Break Evolution Process during Single Fiber Fragmentation Test LA Ahure Powell, RJ Sheridan, S Yucel, B Yucel, E Rust, SR Kalidindi, ... Experimental Techniques 47 (2), 549-549, 2023 | | 2023 |
| MAGNETORHEOLOGICAL FLUIDS EMPLOYING SUBSTITUTION OF NONMAGNETIC FOR MAGNETIC PARTICLES TO INCREASE YIELD STRESS LA AHURE, S LUSTIG, NM WERELEY, J ULICNY Electro-Rheological Fluids And Magneto-Rheological Suspensions, 376-382, 2011 | | 2011 |
| Dimorphic magnetorheological suspensions: Effect of aspect ratio and volume fraction substitution of microwires in fluids consisting of spherical particles JO Karli, JM Krug, NM Wereley, LA Ahure, RC Bell | | |
