Active and inactive components of the streamwise velocity in wall-bounded turbulence
Townsend (J. Fluid Mech., vol. 11, issue 1, 1961, pp. 97–120) introduced the concept of active and inactive motions for wall-bounded turbulent flows, where the active motions are solely responsible for producing the Reynolds shear stress, the key momentum transport term in these flows. While the wal...
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| description | Townsend (J. Fluid Mech., vol. 11, issue 1, 1961, pp. 97–120) introduced the concept of active and inactive motions for wall-bounded turbulent flows, where the active motions are solely responsible for producing the Reynolds shear stress, the key momentum transport term in these flows. While the wall-normal component of velocity is associated exclusively with the active motions, the wall-parallel components of velocity are associated with both active and inactive motions. In this paper, we propose a method to segregate the active and inactive components of the two-dimensional (2-D) energy spectrum of the streamwise velocity, thereby allowing us to test the self-similarity characteristics of the former which are central to theoretical models for wall turbulence. The approach is based on analysing datasets comprising two-point streamwise velocity signals coupled with a spectral linear stochastic estimation based procedure. The data considered span a friction Reynolds number range $Re_{\tau }\sim {{O}}$($10^3$) – ${{O}}$($10^4$). The procedure linearly decomposes the full 2-D spectrum (${\varPhi }$) into two components, ${\varPhi }_{ia}$ and ${\varPhi }_{a}$, comprising contributions predominantly from the inactive and active motions, respectively. This is confirmed by ${\varPhi }_{a}$ exhibiting wall scaling, for both streamwise and spanwise wavelengths, corresponding well with the Reynolds shear stress cospectra reported in the literature. Both ${\varPhi }_{a}$ and ${\varPhi }_{ia}$ are found to depict prominent self-similar characteristics in the inertially dominated region close to the wall, suggestive of contributions from Townsend's attached eddies. Inactive contributions from the attached eddies reveal pure $k^{-1}$-scaling for the associated one-dimensional spectra (where $k$ is the streamwise/spanwise wavenumber), lending empirical support to the attached eddy model of Perry & Chong (J. Fluid Mech., vol. 119, 1982, pp. 173–217). |
| doi_str_mv | 10.1017/jfm.2020.884 |
| format | Article |
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Fluid Mech., vol. 11, issue 1, 1961, pp. 97–120) introduced the concept of active and inactive motions for wall-bounded turbulent flows, where the active motions are solely responsible for producing the Reynolds shear stress, the key momentum transport term in these flows. While the wall-normal component of velocity is associated exclusively with the active motions, the wall-parallel components of velocity are associated with both active and inactive motions. In this paper, we propose a method to segregate the active and inactive components of the two-dimensional (2-D) energy spectrum of the streamwise velocity, thereby allowing us to test the self-similarity characteristics of the former which are central to theoretical models for wall turbulence. The approach is based on analysing datasets comprising two-point streamwise velocity signals coupled with a spectral linear stochastic estimation based procedure. The data considered span a friction Reynolds number range $Re_{\tau }\sim {{O}}$($10^3$) – ${{O}}$($10^4$). The procedure linearly decomposes the full 2-D spectrum (${\varPhi }$) into two components, ${\varPhi }_{ia}$ and ${\varPhi }_{a}$, comprising contributions predominantly from the inactive and active motions, respectively. This is confirmed by ${\varPhi }_{a}$ exhibiting wall scaling, for both streamwise and spanwise wavelengths, corresponding well with the Reynolds shear stress cospectra reported in the literature. Both ${\varPhi }_{a}$ and ${\varPhi }_{ia}$ are found to depict prominent self-similar characteristics in the inertially dominated region close to the wall, suggestive of contributions from Townsend's attached eddies. Inactive contributions from the attached eddies reveal pure $k^{-1}$-scaling for the associated one-dimensional spectra (where $k$ is the streamwise/spanwise wavenumber), lending empirical support to the attached eddy model of Perry & Chong (J. Fluid Mech., vol. 119, 1982, pp. 173–217).</description><identifier>ISSN: 0022-1120</identifier><identifier>EISSN: 1469-7645</identifier><identifier>DOI: 10.1017/jfm.2020.884</identifier><language>eng</language><publisher>Cambridge, UK: Cambridge University Press</publisher><subject>Components ; Computational fluid dynamics ; Decomposition ; Dimensional analysis ; Eddies ; Empirical analysis ; Energy spectra ; Fluid flow ; Hypotheses ; JFM Papers ; Kinematics ; Momentum ; Procedures ; Reynolds number ; Scaling ; Self-similarity ; Shear stress ; Turbulence ; Velocity ; Viscosity ; Vortices ; Wavelengths</subject><ispartof>Journal of fluid mechanics, 2021-03, Vol.914, Article A5</ispartof><rights>The Author(s), 2021. 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Fluid Mech</addtitle><description>Townsend (J. Fluid Mech., vol. 11, issue 1, 1961, pp. 97–120) introduced the concept of active and inactive motions for wall-bounded turbulent flows, where the active motions are solely responsible for producing the Reynolds shear stress, the key momentum transport term in these flows. While the wall-normal component of velocity is associated exclusively with the active motions, the wall-parallel components of velocity are associated with both active and inactive motions. In this paper, we propose a method to segregate the active and inactive components of the two-dimensional (2-D) energy spectrum of the streamwise velocity, thereby allowing us to test the self-similarity characteristics of the former which are central to theoretical models for wall turbulence. The approach is based on analysing datasets comprising two-point streamwise velocity signals coupled with a spectral linear stochastic estimation based procedure. 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Fluid Mech., vol. 119, 1982, pp. 173–217).</description><subject>Components</subject><subject>Computational fluid dynamics</subject><subject>Decomposition</subject><subject>Dimensional analysis</subject><subject>Eddies</subject><subject>Empirical analysis</subject><subject>Energy spectra</subject><subject>Fluid flow</subject><subject>Hypotheses</subject><subject>JFM Papers</subject><subject>Kinematics</subject><subject>Momentum</subject><subject>Procedures</subject><subject>Reynolds number</subject><subject>Scaling</subject><subject>Self-similarity</subject><subject>Shear stress</subject><subject>Turbulence</subject><subject>Velocity</subject><subject>Viscosity</subject><subject>Vortices</subject><subject>Wavelengths</subject><issn>0022-1120</issn><issn>1469-7645</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2021</creationdate><recordtype>article</recordtype><sourceid>8G5</sourceid><sourceid>ABUWG</sourceid><sourceid>AFKRA</sourceid><sourceid>AZQEC</sourceid><sourceid>BENPR</sourceid><sourceid>CCPQU</sourceid><sourceid>DWQXO</sourceid><sourceid>GNUQQ</sourceid><sourceid>GUQSH</sourceid><sourceid>M2O</sourceid><recordid>eNptkF1LwzAUhoMoOKd3_oCAt7YmadI2l2P4BQNv5nVI0hPtaJuZpBv793Zs4I1XhwPPeV_Og9A9JTkltHrauD5nhJG8rvkFmlFeyqwqubhEM0IYyyhl5BrdxLghhBZEVjO0XtjU7gDrocHtoE-L9f3WDzCkiL3D6RtwTAF0v28j4B103rbpMOF4r7suM34cGmhwGoMZOxgs3KIrp7sId-c5R58vz-vlW7b6eH1fLlaZ5ZSkzDBhrCmsJUVVC25M47RzrKok51DW0lhtwZTWaV5MHxWVEI4LmAjGGiFpMUcPp9xt8D8jxKQ2fgzDVKkYl6UUtajlRD2eKBt8jAGc2oa21-GgKFFHb2rypo7e1LFljvIzrnsT2uYL_lL_PfgFPoVxAQ</recordid><startdate>20210305</startdate><enddate>20210305</enddate><creator>Deshpande, Rahul</creator><creator>Monty, Jason P.</creator><creator>Marusic, Ivan</creator><general>Cambridge University Press</general><scope>AAYXX</scope><scope>CITATION</scope><scope>3V.</scope><scope>7TB</scope><scope>7U5</scope><scope>7UA</scope><scope>7XB</scope><scope>88I</scope><scope>8FD</scope><scope>8FE</scope><scope>8FG</scope><scope>8FK</scope><scope>8G5</scope><scope>ABJCF</scope><scope>ABUWG</scope><scope>AEUYN</scope><scope>AFKRA</scope><scope>ARAPS</scope><scope>AZQEC</scope><scope>BENPR</scope><scope>BGLVJ</scope><scope>BHPHI</scope><scope>BKSAR</scope><scope>C1K</scope><scope>CCPQU</scope><scope>DWQXO</scope><scope>F1W</scope><scope>FR3</scope><scope>GNUQQ</scope><scope>GUQSH</scope><scope>H8D</scope><scope>H96</scope><scope>HCIFZ</scope><scope>KR7</scope><scope>L.G</scope><scope>L6V</scope><scope>L7M</scope><scope>M2O</scope><scope>M2P</scope><scope>M7S</scope><scope>MBDVC</scope><scope>P5Z</scope><scope>P62</scope><scope>PCBAR</scope><scope>PQEST</scope><scope>PQQKQ</scope><scope>PQUKI</scope><scope>PRINS</scope><scope>PTHSS</scope><scope>Q9U</scope><scope>S0W</scope><orcidid>https://orcid.org/0000-0003-2700-8435</orcidid><orcidid>https://orcid.org/0000-0003-4433-2640</orcidid><orcidid>https://orcid.org/0000-0003-2777-2919</orcidid></search><sort><creationdate>20210305</creationdate><title>Active and inactive components of the streamwise velocity in wall-bounded turbulence</title><author>Deshpande, Rahul ; 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Fluid Mech</addtitle><date>2021-03-05</date><risdate>2021</risdate><volume>914</volume><artnum>A5</artnum><issn>0022-1120</issn><eissn>1469-7645</eissn><abstract>Townsend (J. Fluid Mech., vol. 11, issue 1, 1961, pp. 97–120) introduced the concept of active and inactive motions for wall-bounded turbulent flows, where the active motions are solely responsible for producing the Reynolds shear stress, the key momentum transport term in these flows. While the wall-normal component of velocity is associated exclusively with the active motions, the wall-parallel components of velocity are associated with both active and inactive motions. In this paper, we propose a method to segregate the active and inactive components of the two-dimensional (2-D) energy spectrum of the streamwise velocity, thereby allowing us to test the self-similarity characteristics of the former which are central to theoretical models for wall turbulence. The approach is based on analysing datasets comprising two-point streamwise velocity signals coupled with a spectral linear stochastic estimation based procedure. The data considered span a friction Reynolds number range $Re_{\tau }\sim {{O}}$($10^3$) – ${{O}}$($10^4$). The procedure linearly decomposes the full 2-D spectrum (${\varPhi }$) into two components, ${\varPhi }_{ia}$ and ${\varPhi }_{a}$, comprising contributions predominantly from the inactive and active motions, respectively. This is confirmed by ${\varPhi }_{a}$ exhibiting wall scaling, for both streamwise and spanwise wavelengths, corresponding well with the Reynolds shear stress cospectra reported in the literature. Both ${\varPhi }_{a}$ and ${\varPhi }_{ia}$ are found to depict prominent self-similar characteristics in the inertially dominated region close to the wall, suggestive of contributions from Townsend's attached eddies. Inactive contributions from the attached eddies reveal pure $k^{-1}$-scaling for the associated one-dimensional spectra (where $k$ is the streamwise/spanwise wavenumber), lending empirical support to the attached eddy model of Perry & Chong (J. Fluid Mech., vol. 119, 1982, pp. 173–217).</abstract><cop>Cambridge, UK</cop><pub>Cambridge University Press</pub><doi>10.1017/jfm.2020.884</doi><tpages>22</tpages><orcidid>https://orcid.org/0000-0003-2700-8435</orcidid><orcidid>https://orcid.org/0000-0003-4433-2640</orcidid><orcidid>https://orcid.org/0000-0003-2777-2919</orcidid><oa>free_for_read</oa></addata></record> |
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| subjects | Components Computational fluid dynamics Decomposition Dimensional analysis Eddies Empirical analysis Energy spectra Fluid flow Hypotheses JFM Papers Kinematics Momentum Procedures Reynolds number Scaling Self-similarity Shear stress Turbulence Velocity Viscosity Vortices Wavelengths |
| title | Active and inactive components of the streamwise velocity in wall-bounded turbulence |
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