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Sl.No Chapter Name MP4 Download Transcript Download
1Lecture 1: The turbulence problemDownloadDownload
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2Lecture 2: Basic hydrodynamics - Governing equationsDownloadDownload
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3Lecture 3: Basic hydrodynamics - Vorticity DownloadDownload
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4Lecture 4: Basic hydrodynamics - Quadratic quantities DownloadDownload
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5Lecture 5: Basic hydrodynamics - Example problems DownloadDownload
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6Lecture 6: Fourier space representation - Definitions DownloadDownload
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7Lecture 7: Fourier space representation - Flow equationsDownloadDownload
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8Lecture 8: Fourier space represenation - Kinetic energyDownloadDownload
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9Lecture 9: Fourier space representation - Vorticity, Kinetic Helicity, and Enstrophy DownloadDownload
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10Lecture 10: Fourier space representation - Examples DownloadDownload
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11Lecture 11: Fourier space representation - Examples (continued) DownloadDownload
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12Lecture 12: Craya-Herring Basis: DefinitionsDownloadDownload
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13Lecture 13: Craya-Herring Basis: Equations of Motion for a TriadDownloadDownload
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14Lecture 14: Craya-Herring Basis: Equations of Motion for an Anticlockwise TriadDownloadDownload
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15Lecture 15: Thermal InstabilityDownloadDownload
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16Lecture 16: Thermal Instabilities ContinuedDownloadDownload
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17Lecture 17: Rotating Convection: Instability and PatternsDownloadDownload
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18Lecture 18: Magnetoconvection: Instability and PatternsDownloadPDF unavailable
19Lecture 19: Nonlinear Saturation: Lorenz EquationDownloadPDF unavailable
20Lecture 20: Patterns, Chaos, and TurbulenceDownloadPDF unavailable
21Lecture 21: Energy Transfers: Mode-to-mode Energy TransfersDownloadPDF unavailable
22Lecture 22: Energy Transfers: Mode-to-mode Energy Transfers (continued)DownloadPDF unavailable
23Lecture 23: Energy Transfers: ExamplesDownloadPDF unavailable
24Lecture 24: Energy Transfers: Spectral Energy Flux and Shell-to-Shell Energy TransferDownloadPDF unavailable
25Lecture 25: Energy Transfers: Fluid Simulations using Spectral Method DownloadPDF unavailable
26Lecture 26: Energy Transfers: Fluid Simulations - Dealiasing DownloadPDF unavailable
27Lecture 27: Kolmogorov's Theory: Energy Spectrum and FluxDownloadPDF unavailable
28Lecture 28: Kolmogorov's Theory: Insights and its Verification with Direct Numerical SimulationDownloadPDF unavailable
29Lecture 29: Kolmogorov's theory: Spectrum and Flux in inertial-dissipation range DownloadDownload
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30Lecture 30: Kolmogorov's four-fifth law: Isotropic Tensor and Correlations DownloadDownload
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31Lecture 31: Kolmogorov's four-fifth law: DerivationDownloadDownload
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32Lecture 32: Kolmogorov's four-fifth law: Derivation (Final steps) DownloadDownload
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33Lecture 33: Enstrophy Spectrum and FluxDownloadPDF unavailable
34Lecture 34: Two-dimensional TurbulenceDownloadPDF unavailable
35Helical turbulenceDownloadPDF unavailable
36Flow with a scalarDownloadPDF unavailable
37Passive scalar turbulence DownloadPDF unavailable
38Stably stratified turbulenceDownloadPDF unavailable
39Turbulent thermal convectionDownloadPDF unavailable
40Flow with a vectorDownloadPDF unavailable
41Lecture 41: MHD Turbulence: FormalismDownloadPDF unavailable
42Lecture 42: MHD Turbulence: Energy TransfersDownloadPDF unavailable
43Lecture 43: MHD Turbulence: Turbulence Models DownloadPDF unavailable
44Lecture 44: MHD Turbulence: DynamoDownloadPDF unavailable