Licheng Li scite author profile

Licheng Li

3Publications

1Citation Statement Received

101Citation Statements Given

How they've been cited

How they cite others

112

101

Affiliations

Lanzhou University

Publications

Order By: Most citations

Revealing the Dynamical Transition of Anisotropy Behind the HOST by Koopman Analysis

Zuo

Chen

et al. 2020

Geophysical Research Letters

View full text Add to dashboard Cite

The hockey-stick transition (HOST), which is depicted by the "local and global shear" assumption, about the turbulence kinetic energy with the averaged flow intensity is noticed widely. However, the intrinsic mechanism of averaged flow influences turbulence kinetic energy via shear and buoyancy is missing. In this research, we deploy the Koopman operator to expose invariant subspaces of the Ri series to identify the quasiperiodic coherent structures from the single tower observation. Analysis of turbulence fluxes and anisotropy demonstrates the mechanism, that is, horizontal kinetic energy coupled with vertical downward flux, whereby anisotropy evolution is changed. Examining the anisotropy invariants changing with kinetic energy reveals a dynamical transition that determines the threshold of HOST. Moreover, the mechanism about how the shear and vertical momentum influences the transition point of HOST is at first given by a group of a quadratic relationship when the anisotropy crossed over the transition point. Plain Language Summary The turbulence intensity is always influenced by submesoscale motions in a nocturnal stable boundary layer. This multiscale interaction can be displayed by the hockey-stick transition, which is depicted by the "local and global shear" assumption. Although this pattern is noticed widely in many different field observations, the intrinsic mechanism of averaged flow influences turbulence kinetic energy via shear and buoyancy is unclear. Because during the interaction, turbulent eddies in the nocturnal stable boundary layer are embedded in the coherent structures, leading to the difficulty in the estimation of the time length of the interaction. In this research, we deploy the Koopman operator to expose invariant subspaces of the Ri series to identify the quasiperiodic coherent structures from the single tower observation. Anisotropy analysis based on the time length-averaged result from the subspaces reveals the existence of the mechanism, that is, horizontal kinetic energy transport coupled with a vertical downward flux, which causes the unique evolution of turbulence anisotropy. Moreover, a dynamical transition is discovered when the anisotropy invariants change with kinetic energy which determines the threshold of HOST by a group of quadratic curves about the shear and vertical momentum when the anisotropy crossed over the transition point.

show abstract

Revealing the Dynamical Transition of Anisotropy behind the HOST by Koopman Analysis

Zuo

Chen

et al. 2020

Preprint

View full text Add to dashboard Cite

The hockey-stick transition (HOST), which is depicted by the "local and global shear" assumption, about the turbulence kinetic energy with the averaged flow intensity is noticed widely. However, the intrinsic mechanism of averaged flow influences turbulence kinetic energy via shear and buoyancy is missing. In this research, we deploy the Koopman operator to expose invariant subspaces of the Ri series to identify the quasiperiodic coherent structures from the single tower observation. Analysis of turbulence fluxes and anisotropy demonstrates the mechanism, that is, horizontal kinetic energy coupled with vertical downward flux, whereby anisotropy evolution is changed. Examining the anisotropy invariants changing with kinetic energy reveals a dynamical transition that determines the threshold of HOST. Moreover, the mechanism about how the shear and vertical momentum influences the transition point of HOST is at first given by a group of a quadratic relationship when the anisotropy crossed over the transition point. Plain Language SummaryThe turbulence intensity is always influenced by submesoscale motions in a nocturnal stable boundary layer. This multiscale interaction can be displayed by the hockey-stick transition, which is depicted by the "local and global shear" assumption. Although this pattern is noticed widely in many different field observations, the intrinsic mechanism of averaged flow influences turbulence kinetic energy via shear and buoyancy is unclear. Because during the interaction, turbulent eddies in the nocturnal stable boundary layer are embedded in the coherent structures, leading to the difficulty in the estimation of the time length of the interaction. In this research, we deploy the Koopman operator to expose invariant subspaces of the Ri series to identify the quasiperiodic coherent structures from the single tower observation. Anisotropy analysis based on the time length-averaged result from the subspaces reveals the existence of the mechanism, that is, horizontal kinetic energy transport coupled with a vertical downward flux, which causes the unique evolution of turbulence anisotropy. Moreover, a dynamical transition is discovered when the anisotropy invariants change with kinetic energy which determines the threshold of HOST by a group of quadratic curves about the shear and vertical momentum when the anisotropy crossed over the transition point.

show abstract

Revealing the Dynamical Transition of Anisotropy behind the HOST by Koopman Analysis

Zuo

Chen

et al. 2020

Preprint

View full text Add to dashboard Cite

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Licheng Li

Revealing the Dynamical Transition of Anisotropy Behind the HOST by Koopman Analysis

Revealing the Dynamical Transition of Anisotropy behind the HOST by Koopman Analysis

Revealing the Dynamical Transition of Anisotropy behind the HOST by Koopman Analysis

Contact Info

Product

Resources

About