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        {
            "id": "229a7e48-1c72-4ee0-9223-af045205a5bc",
            "@context": "http://schema.org",
            "@type": "Dataset",
            "@id": "https://doi.org/10.34711/inptdat.822",
            "url": "https://www.inptdat.de/node/822/",
            "name": "Dual-comb spectroscopy of ammonia formation in non-thermal plasmas",
            "author": [
                {
                    "@type": "Person",
                    "name": "Sadiek, Ibrahim"
                },
                {
                    "@type": "Person",
                    "name": "Fleisher, Adam J."
                },
                {
                    "@type": "Person",
                    "name": "Hayden, Jakob"
                },
                {
                    "@type": "Person",
                    "name": "Huang, Xinyi"
                },
                {
                    "@type": "Person",
                    "name": "Hugi, Andreas"
                },
                {
                    "@type": "Person",
                    "name": "Engeln, Richard"
                },
                {
                    "@type": "Person",
                    "name": "Lang, Norbert"
                },
                {
                    "@type": "Person",
                    "name": "van Helden, Jean-Pierre"
                }
            ],
            "publisher": {
                "@type": "Organisation",
                "name": "INPTDAT"
            },
            "datePublished": "2024-05-22",
            "description": "Plasma-activated chemical transformations promise the efficient synthesis of salient chemical products. However, the reaction pathways that lead to desirable products are often unknown, and key quantum-state-resolved information regarding the involved molecular species is lacking. Here we use quantum cascade laser dual-comb spectroscopy (QCL-DCS) to probe plasma-activated NH3 generation with rotational and vibrational state resolution, quantifying state-specific number densities via broadband spectral analysis. The measurements reveal unique translational, rotational and vibrational temperatures for NH3 products, indicative of a highly reactive, non-thermal environment. Ultimately, we postulate on the energy transfer mechanisms that explain trends in temperatures and number densities observed for NH3 generated in low-pressure nitrogen-hydrogen (N2\u2013H2) plasmas. This dataset provides the supplementary data to the published article.",
            "keywords": "quantum cascade laser dual-comb spectroscopy, plasma-activated NH3 generation"
        }
    ]
}