| 1 |
Single-cylinder engine evaluation of a multi-component Diesel surrogate fuel at partially-premixed and low-temperature combustion modes
Szymkowicz PG, Benajes J
Fuel, 241, 506, 2019 |
| 2 |
Flash points measurements and prediction of biofuels and biofuel blends with aromatic fluids
Fu JX
Fuel, 241, 892, 2019 |
| 3 |
Development of a new jet fuel surrogate and its associated reaction mechanism coupled with a multistep soot model for diesel engine combustion
Yu WB, Tay KL, Zhao FY, Yang WM, Li H, Xu HP
Applied Energy, 228, 42, 2018 |
| 4 |
An optimization method for formulating model-based jet fuel surrogate by emulating physical, gas phase chemical properties and threshold sooting index (TSI) of real jet fuel under engine relevant conditions
Yu WB, Yang WM, Tay KL, Zhao FY
Combustion and Flame, 193, 192, 2018 |
| 5 |
Development of a Diesel Surrogate Fuel Library
Szymkowicz PG, Benajes J
Fuel, 222, 21, 2018 |
| 6 |
Development of an optimization methodology for formulating both jet fuel and diesel fuel surrogates and their associated skeletal oxidation mechanisms
Yu WB, Zhao FY, Yang WM, Tay KL, Xu HP
Fuel, 231, 361, 2018 |
| 7 |
Skeletal mechanism development for a 3-component jet fuel surrogate using semi-global sub-mechanism construction and mechanism reduction
Fang XY, Huang Z, Qiao XQ, Ju DH, Bai XM
Fuel, 229, 53, 2018 |
| 8 |
Hydrocarbons for the next generation of jet fuel surrogates
Kim D, Violi A
Fuel, 228, 438, 2018 |
| 9 |
Single-cylinder engine evaluation of a multi-component diesel surrogate fuel at a part-load operating condition with conventional combustion
Szymkowicz PG, Benajes J
Fuel, 226, 286, 2018 |
| 10 |
Reconstruction of chemical structure of real fuel by surrogate formulation based upon combustion property targets
Won SH, Haas FM, Dooley S, Edwards T, Dryer F
Combustion and Flame, 183, 39, 2017 |
