| 1 |
Mean field coupling mechanisms explaining the impact of the precessing vortex core on the flame transfer function
Luckoff F, Kaiser TL, Paschereit CO, Oberleithner K
Combustion and Flame, 223, 254, 2021 |
| 2 |
On the spurious entropy generation encountered in hybrid linear thermoacoustic models
Meindl M, Silva CF, Polifke W
Combustion and Flame, 223, 525, 2021 |
| 3 |
Scaling and prediction of transfer functions in lean premixed H-2/CH4-flames
AEsoy E, Aguilar JG, Wiseman S, Bothien MR, Worth NA, Dawson JR
Combustion and Flame, 215, 269, 2020 |
| 4 |
Suppression of instabilities of swirled premixed flames with minimal secondary hydrogen injection
Oztarlik G, Selle L, Poinsot T, Schuller T
Combustion and Flame, 214, 266, 2020 |
| 5 |
Combining analytical models and LES data to determine the transfer function from swirled premixed flames
Dupuy F, Gatti M, Mirat C, Gicquel L, Nicoud F, Schuller T
Combustion and Flame, 217, 222, 2020 |
| 6 |
Development and validation study of a 1D analytical model for the response of reheat flames to entropy waves
Gant F, Gruber A, Bothien MR
Combustion and Flame, 222, 305, 2020 |
| 7 |
Consequences of flame geometry for the acoustic response of premixed flames
Steinbacher T, Albayrak A, Ghani A, Polifke W
Combustion and Flame, 199, 411, 2019 |
| 8 |
Frequency Response of Turbulent Partially Premixed Flame Stabilized in Free-Standing Vortex Breakdown
Wysocki S, Syed KJ, Biagioli F
Combustion Science and Technology, 191(5-6), 797, 2019 |
| 9 |
Forced response of laminar non-premixed jet flames
Magina N, Acharya V, Lieuwen T
Progress in Energy and Combustion Science, 70, 89, 2019 |
| 10 |
Influence of flame-holder temperature on the acoustic flame transfer functions of a laminar flame
Mejia D, Miguel-Brebion M, Ghani A, Kaiser T, Duchaine F, Selle L, Poinsot T
Combustion and Flame, 188, 5, 2018 |
