Effects of difference in heating sources on ammonia reactivity: Possibility for photolysis-assisted ammonia combustion

Kenta Tamaoki , Yoshito Ishida , Takuya Tezuka , Hisashi Nakamura
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Abstract

Ammonia (NH3) reactivity in a micro flow reactor with a controlled temperature profile (MFR) is reexamined through species measurements utilizing two heating sources in the MFR: an H2/air flat flame and an electric heater. The maximum wall temperatures (Tw,max) formed in the reactor vary in a range of Tw,max = 1100–1400 K. A stoichiometric NH3/air mixture is tested, and exhaust NH3 is detected by a quadrupole mass spectrometer (QMS). Unexpectedly, NH3 is completely consumed at temperatures at least 100 K lower in the H2/air flat flame case compared to the electric furnace case, despite nearly identical conditions of a MFR characteristic residence time estimated by the wall temperature profiles and the convective flow velocity. Considering the non-thermal characteristics of the two heating sources that the H2/air flat flame emits ultraviolet light, whereas infrared light as thermal radiation is emitted within the electric furnace, the possibility of NH3 photolysis in the H2/air flat flame case is discussed based on literature regarding emissions from the H2/air flames, the transmittance of the quartz tube, and the photodissociation of NH3 in the ultraviolet region. When ultraviolet light emitted from the H2/air flat flame passes through the quartz tube and decomposes NH3 into NH2 and H radicals, these produced radicals enhance the growth of OH radicals, resulting in increased NH3 reactivity. These findings suggest the possibility of photolysis-assisted ammonia combustion, which could be an additional method to overcome the low reactivity of NH3.

不同加热源对氨反应性的影响:光解辅助氨燃烧的可能性
通过利用 MFR 中的两种加热源(H2/空气平焰和电加热器)进行物种测量,重新研究了温度曲线受控的微流反应器(MFR)中的氨(NH3)反应性。反应器中形成的最高壁温(Tw,max)在 Tw,max = 1100-1400 K 的范围内变化。出乎意料的是,尽管根据壁温曲线和对流流速估算的 MFR 特性停留时间条件几乎相同,但与电炉相比,H2/空气平焰情况下 NH3 的完全消耗温度至少低 100 K。考虑到两种加热源的非热特性,即 H2/air 平焰发射紫外线,而电炉内则发射作为热辐射的红外线,根据有关 H2/air 火焰发射、石英管透射率和 NH3 在紫外线区域光解的文献,讨论了在 H2/air 平焰情况下 NH3 光解的可能性。当 H2/air 平面火焰发出的紫外线穿过石英管并将 NH3 分解为 NH2 和 H 自由基时,这些产生的自由基会促进 OH 自由基的生长,从而提高 NH3 的反应活性。这些发现表明了光解辅助氨燃烧的可能性,这可能是克服 NH3 反应性低的另一种方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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