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Mode-locked rotating detonation waves: Experiments and a model equation

James Koch, M. Kurosaka, C. Knowlen, J. Nathan Kutz

2020Physical review. E40 citationsDOIOpen Access PDF

Abstract

Direct observation of a rotating detonation engine combustion chamber has enabled the extraction of the kinematics of its detonation waves. These records exhibit a rich set of instabilities and bifurcations arising from the interaction of coherent wave fronts and global gain dynamics. We develop a model of the observed dynamics by recasting the Majda detonation analog as an autowave process. The solution fronts become attractors of the engine, i.e., mode-locked rotating detonation waves. We find that denotative energy release competes with dissipation and gain recovery to produce the observed dynamics and a bifurcation structure common to other driven-dissipative systems, such as mode-locked lasers.

Topics & Concepts

AutowaveDetonationDissipative systemPhysicsMechanicsMode (computer interface)AttractorDissipationClassical mechanicsDynamics (music)BifurcationExplosive materialNonlinear systemAcousticsThermodynamicsComputer scienceChemistryOperating systemMathematical analysisOrganic chemistryQuantum mechanicsMathematicsAdvanced Fiber Laser TechnologiesCombustion and Detonation ProcessesNonlinear Dynamics and Pattern Formation
Mode-locked rotating detonation waves: Experiments and a model equation | Litcius