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  <title><![CDATA[PhD Defense by Miad Karimi]]></title>
  <body><![CDATA[<p><strong>Miad Karimi</strong><br />
<em>Co-Advisor: Prof. Devesh Ranjan</em></p>

<p><em>Co-Advisor: Prof. Wenting Sun</em></p>

<p><em>will defend a doctoral thesis entitled, </em></p>

<p>Investigation of high-pressure methane and syngas autoignition delay times</p>

<p>&nbsp;</p>

<p><em>On</em></p>

<p><strong>Thursday, August 15 at 2:00 p.m.<br />
MRDC Building 4211</strong><br />
&nbsp;</p>

<p><strong>Abstract</strong></p>

<p>This thesis reports methane (CH<sub>4</sub>) and a syngas mixture (H<sub>2</sub>/CO=95:5) autoignition delay measurements relevant to operating conditions of supercritical carbon dioxide (sCO<sub>2</sub>) power cycle (100 to 300 bar) combustors. To acquire data at these conditions as part of this thesis, a new high-pressure shock tube is designed, fabricated and commissioned.&nbsp; The experiments are conducted for diluted carbon dioxide environments at 100 and 200 bar and at temperatures within the range of approximately 1100&ndash;1400 K. To investigate the chemical effect of CO<sub>2</sub> at supercritical conditions, experiments are conducted at similar pressures and temperatures by substituting CO<sub>2</sub> with an inert bath gas, Ar (argon). Obtaining ignition delay times in Ar bath gas allows to systematically study the chemical effect of CO<sub>2</sub> on ignition chemistry.&nbsp;</p>

<p>Methane ignition delay times are compared to several chemical kinetic models, such as Aramco 2.0, FFCM-1, HP-Mech, USC Mech II and GRI 3.0. For the conditions of this study, predictions of the Aramco 2.0 kinetic model show the overall best agreement with experimental measurements. Following the experimental data, brute-force sensitivity analyses and reaction pathway flux analyses are utilized to gain insight into details of the ignition chemistry of the fuels (CH<sub>4</sub> and H<sub>2</sub>/CO=95:5). These analyses indicate that methyl (CH<sub>3</sub>) recombination to form ethane (C<sub>2</sub>H<sub>6</sub>) and oxidation of CH<sub>3</sub> to form methoxide (CH<sub>3</sub>O) are the most important reactions controlling the ignition behavior of methane at temperatures greater than approximately 1250 K. However, at temperatures below approximately 1250 K, an additional reaction pathway for methyl radicals is found through CH<sub>3</sub>+O<sub>2</sub>+M=CH<sub>3</sub>O<sub>2</sub>+M, which leads to formation of methyldioxidanyl (CH<sub>3</sub>O<sub>2</sub>). This reaction pathway plays a distinct role in dictating the ignition trends at lower temperature conditions. Replacing CO<sub>2</sub> with argon as the bath gas reveals that CO<sub>2</sub> does not have major effects on ignition chemistry of CH<sub>4</sub>.</p>

<p>A similar approach is taken to obtain experimental data at 100 bar and 200 bar for a syngas fuel mixture of 95% H<sub>2</sub> (hydrogen) and 5% CO (carbon monoxide) in CO<sub>2</sub> and Ar bath gasses. Aramco 2.0 kinetic model, FFCM-1 kinetic model, HP-Mech and USC Mech II show good agreement with the measured ignition delay times. Detailed sensitivity analyses of these kinetic models highlight the importance of the third-body reaction between hydrogen atoms (H) and oxygen molecules (O<sub>2</sub>) through H+O<sub>2</sub>+M=HO<sub>2</sub>+M to form hydroperoxyl (HO<sub>2</sub>). In both cases, irrespective of the diluents, this reaction is the most influential reaction to hinder ignition. Ignition delay times obtained from both mixtures not only show a similar trend, but also the same magnitude when compared to the CO<sub>2</sub> mixture. While this observation may suggest that CO<sub>2</sub> has no chemical effect on ignition chemistry, it is found to play a counterbalancing role on syngas ignition at the elevated pressures and temperatures of this study. CO<sub>2</sub> increases the OH (hydroxyl) radical production by colliding with hydrogen peroxide (H<sub>2</sub>O<sub>2</sub>) through H<sub>2</sub>O<sub>2</sub>+M=OH+OH+M. However, it reduces OH production through HO<sub>2</sub>+H=OH+OH due to a lower amount of H radical production compared to Ar mixtures. Therefore, these two effects cancel out the change of OH productions, and CO<sub>2</sub> does not change the ignition delay time of the syngas mixture considered in this study upon comparison with the mixture with Ar bath gas.</p>

<p><strong>Committee</strong></p>

<ul>
	<li>Prof. Devesh Ranjan&ndash; School of Mechanical/Aerospace Engineering (Co-advisor)</li>
	<li>Prof. Wenting Sun&ndash; School of Aerospace Engineering (Co-advisor)</li>
	<li>Prof. Suresh Menon&ndash; School of Aerospace Engineering</li>
	<li>Prof. Timothy Lieuwen&ndash; School of Aerospace Engineering</li>
	<li>Prof. Peter Loutzenhiser&ndash; School of Mechanical Engineering</li>
</ul>

<p>&nbsp;</p>
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