We show that the concept of the effective grain surface area which we introduced in our earlier work, plays a significant role in grain chemistry. E-mail: RXDX-101 manufacturer sonali@csp.res.in Evolution of Pre-biotic Molecules during Collapse of Interstellar Clouds Sandip K. Chakrabarti, S. N. Bose National Centre for Basic Sciences, JD Block, Salt Lake, Kolkata 700098 and Indian Centre for
Space Physics, Kolkata Discovery of amino acids in meteorites click here suggest that many of the complex pre-biotic molecules could indeed be formed during the collapse of the interstellar clouds before the actual star formation took place. We carry out such studies using complete grain and gas chemistry. We use rate equation method, master equation method as well as the Monte-Carlo method to show evolution of lighter molecules in the grain phase and subsequently desorb them to the gas phase and evolve them to produce more complex molecules. Our results generally match with observations AZD6244 purchase for lighter molecules. However, for complex molecules the result is not so conclusive. We believe that this is due to our poor knowledge of the reaction pathways and the reaction cross-section for complex molecules. E-mail: chakraba@bose.res.in Optical Emission Spectroscopy of High-Power Laser-Induced Dielectric Breakdown in
Molecular Gases and Their Mixtures: Investigating Early Stages of Plasma Chemical Action in Planetary Atmospheres Jaroslav Cihelka1,2, Irena Matulková1, Kristéna Sovová1, Michal Kamas1, Petr Kubelík1,2, Martin Ferus1,2, Libor Juha2, Svatopluk
Civiš1 1J. Heyrovsky Institute of Physical Chemistry, Academy of Sciences of the Czech Republic, v.v.i., Dolejškova 3, 182 23 Prague 8, Czech Republic; 2Institute of Physics, Academy of Sciences of the Czech Republic, v.v.i., Na Slovance mTOR inhibitor 2, 182 23 Prague 8, Czech Republic The main goal of this work was simulation of potential high energy processes in early Earth’s atmosphere (as meteorite impact, lightning), which could lead to more complex compounds generated from simple molecular gases (Babánková, Cihelka et al. 2006). Large-scale plasma was created in molecular gases (CH4, N2, D2O) and their mixtures by high-power laser-induced dielectric breakdown (LIDB). Compositions of the mixtures used are those suggested for the early Earth’s atmosphere (Babánková et al. 2006). Time-integrated as well as time-resolved optical emission spectra emitted from the laser spark have been measured and analyzed. The spectra of the plasma generated in the CH4, N2 and D2O containing mixtures are dominated by emission of C2 and CN radicals. These species are precursors of stable products as acetylene and hydrogen cyanide. Occurrence of both species was confirmed in irradiated gaseous mixture by FTIR spectroscopy and gas chromatography (Civiš et al. in press).