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1. Physical, chemical and morphological evolution of incipient soot obtained from molecular dynamics simulation of acetylene pyrolysis

   https://doi.org/10.1016/j.fuel.2024.132197  

   Mukut, Khaled Mosharraf; Ganguly, Anindya; Goudeli, Eirini; Kelesidis, Georgios A; Roy, Somesh P (October 2024, Fuel)

   Incipient soot particles obtained from a series of reactive molecular dynamics simulations were studied to understand the evolution of physical, chemical, and morphological properties of incipient soot. Reactive molecular dynamics simulations of acetylene pyrolysis were performed using ReaxFF potential at 1350, 1500, 1650, and 1800 K. A total of 3324 incipient soot particles were extracted from the simulations at various stages of development. Features such as the number of carbon and hydrogen atoms, number of ring structures, mass, C/H ratio, radius of gyration, surface area, volume, atomic fractal dimension, and density were calculated for each particle. The calculated values of density and C/H ratio matched well with experimental values reported in the literature. Based on the calculated features, the particles were classified in two types: type 1 and type 2 particles. It was found that type 1 particles show significant morphological evolution while type 2 particles undergo chemical restructuring without any significant morphological change. The particle volume was found to be well-correlated with the number of carbon atoms in both type 1 and type 2 particle, whereas surface area was found to be correlated with the number of carbon atoms only for type 1 particles. A correlation matrix comparing the level of correlation between any two features for both type 1 and type 2 particle was created. Finally, based on the calculated statistics, a set of correlations among various physical and morphological parameters of incipient soot was proposed. 

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2. Internal Structure of Incipient Soot from Acetylene Pyrolysis Obtained via Molecular Dynamics Simulations

   https://doi.org/10.1021/acs.jpca.4c01548  

   Mukut, Khaled Mosharraf; Ganguly, Anindya; Goudeli, Eirini; Kelesidis, Georgios A; Roy, Somesh P (July 2024, The Journal of Physical Chemistry A)

   A series of reactive molecular dynamics simulations is used to study the internal structure of incipient soot particles obtained from acetylene pyrolysis. The simulations were performed using ReaxFF potential at four different temperatures. The resulting soot particles are cataloged and analyzed to obtain statistics of their mass, volume, density, C/H ratio, number of cyclic structures, and other features. A total of 3324 incipient soot particles were analyzed in this study. Based on their structural characteristics, the incipient soot particles are classified into two classes, referred to as type 1 and type 2 incipient soot particles in this work. The radial distribution of density, cyclic (5-, 6-, or 7-member rings) structures, and C/H ratio inside the particles revealed a clear difference in the internal structure between type 1 and type 2 particles. These classes were further found to be well represented by the size of the particles, with smaller particles in type 1 and larger particles in type 2. The radial distributions of ring structures, density, and C/H ratio indicated the presence of a dense core region in type 2 particles. In contrast, no clear evidence of the presence of a core was found in type 1 particles. In type 2 incipient soot particles, the boundary between the core and shell was found to be around 50%–60% of the particle radius of gyration. 

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3. Investigation of soot precursor molecules during inception by acetylene pyrolysis using reactive molecular dynamics

   https://doi.org/10.5194/ar-3-185-2025  

   Ganguly, Anindya; Mukut, Khaled Mosharraf; Roy, Somesh; Kelesidis, Georgios; Goudeli, Eirini (January 2025, Aerosol Research)

   Abstract. Soot inception by acetylene pyrolysis at 1350–1800 K is investigated using reactive molecular dynamics. The composition and chemical structure of soot precursor molecules formed during inception are elucidated. During soot inception, increasing the process temperature leads to faster depletion of C2H2 molecules and faster formation of C2H3, C2H4, C2H6, CH4, and C2 with the concurrent appearance of H2 molecules. Small molecules consisting of 1–5 C atoms (C1–C5) are formed due to reactive collisions and grow further to larger hydrocarbon compounds consisting of 6–10 C atoms. At initial stages of inception, prior to the formation of incipient soot, three-member rings are formed, which are associated with the formation of compounds with fewer than 10 C atoms. Once incipient soot is formed, the number of C1–C10 compounds and the number of three-member rings drop, while the number of five- and six-member rings increases, indicating that the formation of larger rings is associated with the growth of soot clusters. The chemical structure of soot precursor molecules obtained by bond order analysis reveals that molecules with up to 10 C atoms are either linear or branched aliphatic compounds or may contain three-member rings fused with aliphatic components. Molecules with more than 10 C atoms often exhibit structures composed of five- or six-member C rings, decorated by aliphatic components. The identification of molecular precursors contributing to soot inception provides crucial insights into soot formation mechanisms, pinpointing potential pathways of soot formation during combustion. 

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4. Experimental evidence of kinetically driven mechanisms for soot inception

   https://doi.org/10.1038/s42004-025-01552-9  

   Michelsen, Hope A; Campbell, Matthew F; Johansson, K Olof; Schrader, Paul E; Wilson, Kevin R (December 2025, Communications Chemistry)

   Soot is known for its enormous and pervasive negative impacts on human health and the environmental, but there much about soot that is not well known, including the precursors and chemical mechanisms involved in its formation. Many studies have characterized species associated with incipient particles, i.e., the first particles produced during soot formation. These studies provide insight into inception mechanisms, the pathways leading from gas-phase precursors to condensed-phase particles. Potential inception mechanisms involve one (or a combination) of two classes of pathways: physical nucleation, in which precursors undergo a thermodynamic phase change and are bound together by electrostatic forces, and chemical clustering, in which precursors react to form covalently bound clusters. In a recent paper, Shao et al.1 concluded that soot inception occurs through physical nucleation and claimed to have provided direct evidence of such a mechanism. We demonstrate that this conclusion is inconsistent with (1) the consensus of published work, (2) the data, theory, and analysis on which this conclusion is nominally based, and (3) the second law of thermodynamics. We show that, contrary to their conclusions, their experimental and theoretical results provide evidence for a chemical-clustering soot-inception mechanism. 

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5. An easy but quantitative assessment of soot production rate and its dependence on temperature and pressure

   https://doi.org/10.1016/j.proci.2024.105292  

   Gleason, Kevin; Carbone, Francesco; Gomez, Alessandro (January 2024, Proceedings of the Combustion Institute)

   The challenge of soot emission persists in combustion research due to the complexities of tracking the crucial stages of growth from fuel to soot nuclei and ultimately mature particles. Studying soot formation in flames often requires a sophisticated approach, involving detailed measurements of gaseous soot precursors and soot particles using multiple complementary diagnostics. On the other end of the spectrum of studies are simpler methods that capture the sooting tendency using a single index, akin to the cetane number in compression ignition engines and the octane number in spark ignition engines. This article seeks a middle ground, aiming to quantify the soot production rate while maintaining the simplicity of single-index characterizations. The approach involves establishing counterflow diffusion flames, measuring soot volume fraction through pyrometry, and accurately computing velocity and temperature profiles using a commercial code. These data allow for the quantification of the production rate from the soot governing equation. The methodology is applied to counterflow ethylene diffusion flames to examine the temperature dependence of the soot production rate across peak temperatures varying by several hundred degrees and pressures in the 1–32 atm range. The soot production rate per unit flame area falls within the range of 10􀀀 7–10􀀀 3 g/(cm2s) range and, when normalized with respect to the carbon flux, it ranges between 10􀀀 6 and nearly 10􀀀 2. On a logarithmic scale, it linearly correlates with the peak temperature at a fixed pressure. Although this study deals only with flames of ethylene, the approach can be generalized to any fuel. The resulting database should be valuable not only for industry practitioners but also to the scientific community for the global validation of detailed soot models. 

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