| 1 |
Structural validation of a thermoplastic composite wind turbine blade with comparison to a thermoset composite blade
Murray RE, Beach R, Barnes D, Snowberg D, Berry D, Rooney S, Jenks M, Gage B, Boro T, Wallen S, Hughes S
Renewable Energy, 164, 1100, 2021 |
| 2 |
Techno-economic analysis of a megawatt-scale thermoplastic resin wind turbine blade
Murray RE, Jenne S, Snowberg D, Berry D, Cousins D
Renewable Energy, 131, 111, 2019 |
| 3 |
Fusion joining of thermoplastic composite wind turbine blades: Lap-shear bond characterization
Murray RE, Roadman J, Beach R
Renewable Energy, 140, 501, 2019 |
| 4 |
Towing tank testing of passively adaptive composite tidal turbine blades and comparison to design tool
Murray RE, Ordonez-Sanchez S, Porter KE, Doman DA, Pegg MJ, Johnstone CM
Renewable Energy, 116, 202, 2018 |
| 5 |
Added-mass effects on a horizontal-axis tidal turbine using FAST v8
Murray RE, Thresher R, Jonkman J
Renewable Energy, 126, 987, 2018 |
| 6 |
Parameters Governing Ruthenium Sawhorse-Based Decarboxylation of Oleic Acid
Doll KM, Bantchev GB, Walter EL, Murray RE, Appell M, Lansing JC, Moser BR
Industrial & Engineering Chemistry Research, 56(4), 864, 2017 |
| 7 |
Co-sputtered metal and polymer nanocomposite films and their electrical responses for gas sensing application
Rujisamphan N, Murray RE, Deng F, Supasai T
Applied Surface Science, 368, 114, 2016 |
| 8 |
Improvement of Lubricant Materials Using Ruthenium Isomerization
Doll KM, Walter EL, Bantchev GB, Jackson MA, Murray RE, Rich JO
Chemical Engineering Communications, 203(7), 901, 2016 |
| 9 |
Analysis and Properties of the Decarboxylation Products of Oleic Acid by Catalytic Triruthenium Dodecacarbonyl
Moser BR, Knothe G, Walter EL, Murray RE, Dunn RO, Doll KM
Energy & Fuels, 30(9), 7443, 2016 |
| 10 |
Experimental study of the phase change and energy characteristics inside a cylindrical latent heat energy storage system: Part 1 consecutive charging and discharging
Murray RE, Groulx D
Renewable Energy, 62, 571, 2014 |
