[ { "id": "authors:nqaej-yv378", "collection": "authors", "collection_id": "nqaej-yv378", "cite_using_url": "https://authors.library.caltech.edu/records/nqaej-yv378", "type": "book_section", "title": "Simulation of\u00a0K-Type and\u00a0H-Type Transition Using the\u00a0Nonlinear One-Way Navier-Stokes Approach", "book_title": "Proceedings of the 10th IUTAM Symposium on Laminar-Turbulent Transition", "author": [ { "family_name": "Sleeman", "given_name": "Michael K.", "orcid": "0000-0001-5949-9289", "clpid": "Sleeman-Michael-K" }, { "family_name": "Lakebrink", "given_name": "Matthew T." }, { "family_name": "Colonius", "given_name": "Tim", "orcid": "0000-0003-0326-3909", "clpid": "Colonius-T" } ], "abstract": "

In principle, transition to turbulence can be studied using direct numerical simulation (DNS) and large eddy simulation (LES), but these approaches are limited by their large computational cost. The Nonlinear One-Way Navier-Stokes (NOWNS) equations have recently been developed and applied to study the early stages of boundary layer transition, and it was demonstrated that they can accurately replicate DNS results with similar accuracy to the nonlinear parabolized stability equations (NPSE) [15]. While having greater computational cost than NPSE, NOWNS is a more robust, convergent parabolization of the governing equations and succeeds for stronger nonlinearity where NPSE fails. In this work, we use NOWNS to reproduce (to the extent possible) the H- and K-type transition scenarios simulated using DNS by Sayadi et al. 

", "doi": "10.1007/978-981-96-9829-5_19", "issn": "1875-3507", "isbn": "9789819698288", "publisher": "Springer Nature Singapore", "place_of_publication": "Singapore", "publication_date": "2026", "pages": "143-149" } ]