Chen Gu scite author profile

The burner stabilized stagnation flame technique coupled with micro-orifice probe sampling and mobility sizing has evolved into a useful tool for examining the evolution of the particle size distribution of nascent soot in laminar premixed flames. Several key aspects of this technique are examined through a multi-university collaborative study that involves both experimental measurement and computational modeling. Key issues examined include (a) data reproducibility and facility effects using four burners of different sizes and makers over three different facilities, (b) the mobility diameter and particle mass relationship, and (c) the degree to which the finite orifice flowrate affects the validity of the boundary condition in a pseudo one dimensional stagnation flow flame formulation. The results indicate that different burners across facilities yield nearly identical results after special attention is paid to a range of experimental details, including a proper selection of the sample dilution ratio and quantification of the experimental flame boundary conditions. The mobility size and mass relationship probed by tandem mass and mobility measurement shows that nascent soot with mobility diameter as small as 15 nm can deviate drastically from the spherical shape. Various non-spherical morphology models using a mass density value of 1.5g/cm3 can reconcile this discrepancy in nascent soot mass. Lastly, two-dimensional axisymmetric simulations of the experimental flame with and without the sample orifice flow reveal several problems of the pseudo one-dimensional stagnation flow flame approximation. The impact of the orifice flow on the flame and soot sampled, although small, is not negligible. Specific suggestions are provided as to how to treat the non-ideality of the experimental setup in experiment and model comparisons

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Particle size distribution of nascent soot in lightly and heavily sooting premixed ethylene flames

Lin

Camacho

et al. 2016

Combustion and Flame

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New Insights into Thermal Decomposition of Polycyclic Aromatic Hydrocarbon Oxyradicals

et al. 2014

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Thermal decompositions of polycyclic aromatic hydrocarbon (PAH) oxyradicals on various surface sites including five-membered ring, free-edge, zigzag, and armchair have been systematically investigated by using ab initio density functional theory B3LYP/6-311+G(d,p) basis set. The calculation based on Hückel theory indicates that PAHs (3H-cydopenta[a]anthracene oxyradical) with oxyradicals on a five-membered ring site have high chemical reactivity. The rate coefficients of PAH oxyradical decomposition were evaluated by using Rice-Ramsperger-Kassel-Marcus theory and solving the master equations in the temperature range of 1500-2500 K and the pressure range of 0.1-10 atm. The kinetic calculations revealed that the rate coefficients of PAH oxyradical decomposition are temperature-, pressure-, and surface site-dependent, and the oxyradical on a five-membered ring is easier to decompose than that on a six-membered ring. Four-membered rings were found in decomposition of the five-membered ring, and a new reaction channel of PAH evolution involving four-membered rings is recommended.

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Potential for reducing GHG emissions and energy consumption from implementing the aluminum intensive vehicle fleet in China

Han

Peng

et al. 2010

Energy

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Mobility size distributions of soot in premixed propene flames

Lin

Camacho

et al. 2016

Combustion and Flame

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Chen Gu

Mobility size and mass of nascent soot particles in a benchmark premixed ethylene flame

Particle size distribution of nascent soot in lightly and heavily sooting premixed ethylene flames

New Insights into Thermal Decomposition of Polycyclic Aromatic Hydrocarbon Oxyradicals

Potential for reducing GHG emissions and energy consumption from implementing the aluminum intensive vehicle fleet in China

Mobility size distributions of soot in premixed propene flames

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