Your search keyword '"Karina Castillo"' showing total 2 results

1. Evidence for the coupling of refill liquids content and new particle formation in electronic cigarette vapors

Author

Oluwabunmi, Dada, Karina, Castillo, Miranda, Hogan, Marie-Cecile G, Chalbot, and Ilias G, Kavouras

Subjects

Glycerol, Flavoring Agents, Multidisciplinary, E-Cigarette Vapor, Vaping, Humans, Electronic Nicotine Delivery Systems, Propylene Glycol

Abstract

The size and chemical content of particles in electronic cigarette vapors (e-vapors) dictate their fate in the human body. Understanding how particles in e-vapors are formed and their size is critical to identifying and mitigating the adverse consequences of vaping. Thermal decomposition and reactions of the refill liquid (e-liquid) components play a key role in new particles formation. Here we report the evolution of particle number concentration in e-vapors over time for variable mixtures of refill e-liquids and operating conditions. Particle with aerodynamic diameter 3) of e-vapors particles. Two events of increasing particle number concentration were observed, 2–3 s after puff completion and a second 4–5 s later. The intensity of each event varied by the abundance of propylene glycol, glycerol, and flavorings in e-liquids. Propylene glycol and glycerol were associated with the first event. Flavorings containing aromatic and aliphatic unsaturated functional groups were strongly associated with the second event and to a lesser extent with the first one. The results indicate that particles in e-vapors may be formed through the heteromolecular condensation of propylene glycol, glycerol, and flavorings, including both parent chemicals and/or their thermal decomposition products.

Published

2022

2. Synthesis and characterization of 1,2,3,4 tetrahydroquinoline intercalated into MoS2 in search of cleaner fuels

Author

Felicia S. Manciu, Jason G. Parsons, Karina Castillo, and Russell R. Chianelli

Subjects

X-ray absorption spectroscopy, Materials science, Mechanical Engineering, Coordination number, Intercalation (chemistry), Inorganic chemistry, Infrared spectroscopy, Condensed Matter Physics, Spectral line, Crystallography, Mechanics of Materials, Molybdenite, General Materials Science, Dehydrogenation, Absorption (chemistry)

Abstract

Two different morphologies of MoS2 (short and long sheets) were utilized to elucidate the intercalation mechanism of 1,2,3,4 tetrahydroquinoline (THQ). MoS2 (short sheets) and molybdenite (MB) (long sheets) were exfoliated and restacked in the presence of THQ. The x-ray diffraction patterns of both samples show a new reflection in the 001 plane, which implies a lowering of symmetry and corresponds to an expansion of the layers by approximately 12.3 Å. In the MoS2-THQ sample, 80% of the MoS2 was intercalated and 20% remained stacked. In the MB-THQ sample, 30% of MB was intercalated while 70% remained stacked. X-ray absorption structure (XAS) studies showed changes in atomic geometry and coordination. The x-ray absorption near-edge spectra showed shifts in the geometry of the intercalated MoS2 and MB sample compared to the unintercalated samples. Extended x-ray absorption fine structure studies showed lower coordination numbers compared to the untreated samples. Infrared spectroscopy characterization of these same samples suggests intercalation and partial dehydrogenation of the THQ.

Published

2007