Program overview
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Monday, March 30 |
Tuesday, March 31 |
Wednesday, April 1 |
Thursday, April 2 |
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8:00 - 9:00 |
Registration + |
Registration / from 8:50: Welcome speech |
Registration |
Registration |
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9:00 – 10.00 |
Plenary lecture - F. Battin-Leclerc What do we really know about the low temperature oxidation of alkanes? |
Plenary lecture - A.A. Konnov Temperature and pressure dependence of the laminar burning velocities: experiments and modelling. |
Plenary lecture - A. M. Starik Kinetic processes in complex burning plasma Closing remarks |
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10:00 – 10:30 |
Refreshment |
Refreshment |
Refreshment |
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10:00 – 13:00 |
Posters |
Posters |
Posters |
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12:00 – 14:00 |
Lunch |
Lunch |
Lunch |
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14:00 – 15:00 |
Plenary lecture - E. Mastorakos Gas turbine combustor ignition: simulations and experiments |
Plenary lecture - H. Pitsch DNS and models for premixed turbulent combustion |
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Refreshment |
Refreshment |
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15:00 – 18:00 |
Posters |
Posters |
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18:00 – 19:00 |
Elsevier lecture – Katie Eve How to get published in a scientific journal, for early career researchers |
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19:00 - |
Welcome reception |
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Banquet |
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The share of the posters according to their topics:
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1. |
KINETICS |
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1.01 |
Thermochemistry and thermodynamics |
3 |
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1.02 |
Rate coefficients of elementary reactions - experimental determinations |
5 |
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1.03 |
Rate coefficients of elementary reactions - theoretical calculations |
10 |
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1.04 |
Mechanism analysis and reduction |
11 |
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1.05 |
Uncertainty quantification and mechanism optimization |
5 |
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1.06 |
Oxidation of hydrogen and syngas |
0 |
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1.07 |
High temperature oxidation of hydrocarbons |
11 |
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1.08 |
High temperature oxidation of alcohols, ketons and other organics |
3 |
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1.09 |
Pyrolysis and low temperature oxidation |
17 |
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1.10 |
NOx and nitrogen reactions |
2 |
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1.11 |
SOx and sulfur reactions; halogenated species reactions |
1 |
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1.12 |
Soot, PAH and aerosol kinetics |
13 |
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1.13 |
Inorganics and metals |
0 |
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1.14 |
Plasma chemistry and reactions of ionic species |
5 |
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1.15 |
Other |
2 |
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total |
88 |
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2. |
PRACTICAL SYSTEMS |
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2.01 |
Reciprocating engines |
14 |
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2.02 |
Gas turbines |
18 |
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2.03 |
Rockets and ramjets |
3 |
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2.04 |
Furnaces and incinerators |
6 |
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2.05 |
Fluidized beds |
0 |
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2.06 |
Pulsed combustors |
0 |
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2.07 |
Fuel cells |
1 |
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2.08 |
Combustion control |
3 |
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2.09 |
Combustion synthesis |
5 |
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2.10 |
New technologies |
6 |
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2.11 |
Other |
3 |
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total |
59 |
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3. |
EXPLOSIONS |
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3.01 |
Gaseous |
6 |
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3.02 |
Condensed phase |
0 |
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3.03 |
Dust and droplet |
0 |
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3.04 |
Autoignition and thermal explosions |
5 |
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3.05 |
Detonations |
2 |
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3.06 |
Other |
0 |
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total |
13 |
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4. |
DIAGNOSTICS |
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4.01 |
Lasers |
17 |
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4.02 |
Spectroscopic and photographic methods |
10 |
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4.03 |
Probes |
2 |
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4.04 |
Other |
1 |
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total |
30 |
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5. |
TRANSPORT |
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5.01 |
Conductive and convective heat transfer |
0 |
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5.02 |
Mass transfer |
0 |
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5.03 |
Transport properties |
1 |
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5.04 |
Radiation, spectra, excited species |
0 |
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5.05 |
Other |
0 |
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total |
1 |
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6. |
FIRE |
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6.01 |
Fire dynamics |
2 |
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6.02 |
Flame spread |
1 |
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6.03 |
Compartment fires |
2 |
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6.04 |
Large scale fires |
0 |
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6.05 |
Inhibitors |
0 |
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6.06 |
Microgravity |
2 |
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6.07 |
Other |
0 |
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total |
7 |
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7. |
FLAMES |
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7.01 |
Laminar flame velocity measurements |
10 |
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7.02 |
Premixed, laminar |
14 |
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7.03 |
Premixed, turbulent |
19 |
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7.04 |
Non-premixed and partially premixed, laminar |
9 |
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7.05 |
Non-premixed and partially premixed, turbulent |
21 |
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7.06 |
Inhibition, flame quenching or extinction |
1 |
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7.07 |
Flame stabilization |
10 |
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7.08 |
Other |
6 |
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total |
90 |
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8. |
HETEROGENEOUS COMBUSTION | |
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8.01 |
Aerosols, droplets, sprays and dusts |
9 |
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8.02 |
Coal, char, polymers, biomass, waste |
21 |
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8.03 |
Metals |
1 |
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8.04 |
Solid propellants and explosives |
2 |
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8.05 |
Catalytic combustion |
5 |
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8.06 |
Porous media |
3 |
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8.07 |
Other |
1 |
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total |
42 |