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Feasibility study of hydrogen-ammonia synergistic combustion in scramjets across broad Mach ranges

Xin Yi Song, Zun Cai, Jianheng Ji, Zihang Chen, Taiyu Wang, Fan Li, Mingbo Sun

2025Nature Communications9 citationsDOIOpen Access PDF

Abstract

Ammonia shows advantages over hydrocarbon fuels for high-Mach scramjet engines, including superior cooling capacity and carbon-free combustion. However, its operation at lower Mach numbers remains challenging. Here, we successfully demonstrate ammonia-hydrogen ignition at Mach 3 and sustained combustion at Mach 6, confirming the feasibility of hydrogen-ammonia synergistic supersonic combustion. Compared to hydrogen combustion, ammonia addition at low Mach numbers does not alter flame paths but increases flame establishment times by 57.1% upstream and 100% downstream. Both global flame establishment and cavity ignition times are longer under the upstream scheme. At high Mach numbers, two distinct combustion modes are observed. Upstream hydrogen injection ignites more ammonia and produces more intense combustion than downstream injection. These results demonstrate the feasibility of ammonia-fueled scramjets operating across a broad Mach range. Ammonia offers benefits like easy storage, high cooling capacity, and carbon-free combustion for high-Mach scramjets, but its low-Mach operation is challenging. Here, authors demonstrate the feasibility of ammonia-hydrogen ignition at Mach 3 and sustained combustion at Mach 6.

Topics & Concepts

Mach numberScramjetCombustionSupersonic speedIgnition systemDrag divergence Mach numberMechanicsAmmoniaHydrogenMach waveNuclear engineeringEnvironmental scienceMaterials scienceUpstream (networking)Aerospace engineeringHypersonic speedAdiabatic flame temperatureChemistryFlammability limitCombustorComputational Fluid Dynamics and AerodynamicsCombustion and flame dynamicsRocket and propulsion systems research