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200 10$aBeethoven after Napoleon$b[electronic resource] $epolitical romanticism in the late works /$fStephen Rumph
210   $aBerkeley $cUniversity of California Press$dc2004
215   $a1 online resource (307 p.)
225 1 $aCalifornia studies in 19th century music ;$v14
300   $aDescription based upon print version of record.
311   $a0-520-23855-9 
320   $aIncludes bibliographical references (p. 267-278) and index.
327   $aA kingdom not of this world -- The heroic sublime -- Promethean history -- 1809 -- Contrapunctus I: prelude and fugue -- Contrapunctus II: double fugue -- Androgynous utopias -- Vox populi, vox dei -- A  modernist epilogue.
330   $aIn this provocative analysis of Beethoven's late style, Stephen Rumph demonstrates how deeply political events shaped the composer's music, from his early enthusiasm for the French Revolution to his later entrenchment during the Napoleonic era. Impressive in its breadth of research as well as for its devotion to interdisciplinary work in music history, Beethoven after Napoleon challenges accepted views by illustrating the influence of German Romantic political thought in the formation of the artist's mature style. Beethoven's political views, Rumph argues, were not quite as liberal as many have assumed. While scholars agree that the works of the Napoleonic era such as the Eroica Symphony or Fidelio embody enlightened, revolutionary ideals of progress, freedom, and humanism, Beethoven's later works have attracted less political commentary. Rumph contends that the later works show clear affinities with a native German ideology that exalted history, religion, and the organic totality of state and society. He claims that as the Napoleonic Wars plunged Europe into political and economic turmoil, Beethoven's growing antipathy to the French mirrored the experience of his Romantic contemporaries. Rumph maintains that Beethoven's turn inward is no pessimistic retreat but a positive affirmation of new conservative ideals.
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200 10$a31st International Symposium on Shock Waves 1 $eFundamentals /$fedited by Akihiro Sasoh, Toshiyuki Aoki, Masahide Katayama
205   $a1st ed. 2019.
210  1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2019.
215   $a1 online resource (xx, 1234 pages) $cillustrations (some color)
311 1 $a3-319-91019-1 
327   $aChapter1.Aerodynamic Testing at Duplicated Hypersonic Flight Conditions with Hyper-Dragon -- Chapter2.Shock wave research: Remembrance of Professor I. I. Glass -- Chapter3.Legacy at T5 -- Chapter4.Experimental studies of shock wave phenomena at the Ben Gurion University ? A Review -- Chapter5.Shock Compression Spectroscopy Under a Microscope -- Chapter6.Research on Shock-induced Aerothermodynamics for Future Planetary Explorations -- Chapter7.Kinetic shock Tubes: Recent developments for The study of homogeneous and heterogeneous chemical processs -- Chapter8.Structure and Unsteadiness of 3D Shock Wave / Turbulent Boundary Layer Interactions. -- Chapter9.Propagation Behavior and Mitigation of Shock Wave along Water inside a Rectangular Tube -- Chapter10.Dust Lofting behind shock waves what is the dominate Lofting Mechanism -- Chapter11.Development of a fast running method for blast wave propagation -- Chapter12.On the Energy Exchange Mechanisms Controlling Blast and Fragment Evolution in a Responding Stone Pipe  -- Chapter13.Interaction of a Blast Wave with a Material Interface -- Chapter14.Laboratory simulation of explosions using conical shock tubes -- Chapter15.Shock Tube Study of the Effect of Nitric Oxide Addition on Ignition Delay Times of n-Dodecane/Air Mixtures -- Chapter16.Ignition Delay Times of Methane and Hydrogen Highly Diluted in Carbon Dioxide -- Chapter17.A Study of the Chemiluminescence of ??*, ??*, ?2* and ??2* during the Oxidation of C2H2 behind Reflected Shock Waves  -- Chapter18.A Study on Soot Formation Characteristics of a Gasoline Surrogate Fuel Using a Shock Tube -- Chapter19.Effect of Dimethyl Methylphosphonate (DMMP) Addition on H2, CH4, and C2H4 ignition Behind Reflected Shock Waves -- Chapter20.CO and H2O Time-histories in a Shock-heated H2S/CH4 Blend near Atmospheric Pressure -- Chapter21.Thermochemical nonequilibrium modeling of O2 -- Chapter22.State-Resolved Transport Properties of Electronically Excited High-Temperature Flows behind Strong Shock Waves -- Chapter23.Oxygen Catalytic Recombination on Titanium Surface -- Chapter24.Computations of a Shock Layer Flow with a Vibrational-Specific Kinetics Model -- Chapter25.A One-dimensional Modeling of Seed-electron Generation and Electron Avalanche in Laser-supported Detonation -- Chapter26.PLIF-based concentration measurement of OH behind the blast wave emanating from an oxy-hydrogen detonation-driven shock tube -- Chapter27.Flame Propagation over the Heat Absorbing Substrate -- Chapter28.Propagation Mechanism of Detonations in Rough Walled Tube -- Chapter29.Effect of hydrodynamic instabilities on the development of hydrogen-air flame -- Chapter30.Characteristics of Crumpling Behavior of Graphene Oxide and Its Effects on Deflagration-to-Detonation Transition -- Chapter31.Detonation decay and flame propagation through a channel with porous walls -- Chapter32.Gas Flow with Stabilized Detonation in a Plane Channel -- Chapter33.Numerical Investigation on Vibrational Nonequilibrium Effect on ZND detonation model -- Chapter34.Stabilities of Rotating Detonation -- Chapter35.The influence of shock reflections on detonation re-initiation -- Chapter36.Experimental studies around shock tube for dynamic calibrations of high-frequency pressure transducers -- Chapter37.Effect of Imaging Blurring on 3D Computed Tomography of Chemiluminescence -- Chapter38.Time-Resolved Optical Flow of Supersonic Beveled Nozzles -- Chapter39.The Effect of Adaptive Sampling on Fluorescence Velocimetry Measurements in High-Speed Flows -- Chapter40.High-resolution background oriented schlieren technique for a laser-induced underwater shock wave -- Chapter41.Evaluation of the effect of an air plasma on the degradation of metallic coatings based on an analysis of the emission from the air behind the front of strong shock waves in the spectral range of 120?400 nm  -- Chapter42.Application of NO Laser Induced Fluorescence in JF-10 Detonation-Driven Shock Tunnel -- Chapter43.Molecular Tagging Velocimetry of NH Fluorescence ina High-enthalpy Rarefied Gas Flow -- Chapter44.Measurements of Jet A-1 Vapor Concentration Using Quantum Cascade Laser -- Chapter45.Temperature Measurement in a Shock Tunnel Using Tunable Diode Laser Absorption Spectroscopy -- Chapter46.Measurement and Formulation of Velocity, Attitude and Trajectory of Moving Object Using Magnet-Coil Method for High-Speed Penetration Experiment -- Chapter47.Investigations of density field on a flat plate shock-boundary layer interaction at Hypersonic speeds using BOS -- Chapter48.Schlieren Tomography to Visualise Three Dimensional Supersonic Flows -- Chapter49.Interaction of a planar shock wave with a water surface -- Chapter50.Basic Experiment on Focusing Schieren PIV Method with LED Light Source -- Chapter51.Boundary-Layer Transition Detection at High Enthalpy Flow Conditions using Temperature-Sensitive Paint  -- Chapter52.Development of Sprayable Ultrafast-PSP for Unsteady Flow -- Chapter53.Three-Dimensional Measurement of the Lateral Jet / Cross FlowInteraction Field by Colored-Grid Background Oriented Schlieren (CGBOS) Technique -- Chapter54.Numerical Investigation of Dust Lifting Induced by Vertical Shock Wave -- Chapter55.Gas Surface Interaction of Carbon Ablator in a Shock Tube -- Chapter56.Numerical Simulations of Shock Wave Interaction with a Water Droplet by Sharp Interface Methods -- Chapter57.High Order Hybrid Compact-WENO-Z Finite Difference Scheme for Hyperbolic Conservation Laws -- Chapter58.A fast mathematical modelling method for aerodynamic-heating predictions -- Chapter59.A Multi-Space Interrelation Theory for Correlating Aerodynamic Data from Hypersonic Ground Testing -- Chapter60.Reynolds Stress Models for Shock ? Turbulence Interaction -- Chapter61.On the analysis of full-spectrum k-distributions databases for thermal radiation in shock waves within CO2 rich atmospheres -- Chapter62.Measurement of Electron Density by Heterodyne Interferometer for Atmospheric Pressure Plasmas -- Chapter63.Parametrical Quasiresonant Amplification of Alfven Waves in Heat-Releasing Isentropic Unstable Medium  -- Chapter64.Two-Dimensional MHD Structures in Heat-Releasing Plasma -- Chapter65.Mode transition from fast gas-ionization wave to laser-supported detonation wave -- Chapter66.Gas-Dynamic Flow behind Shock Wave Initiated by a Sliding Surface Discharge Channel -- Chapter67.Jet Formation of SF6 Bubble Induced by Incident and Reflected Shock Waves -- Chapter68.Interaction of Cylindrical Converging Shock Wave with SF6 Gas Bubble -- Chapter69.Numerical Study on Converging Richtmyer-Meshkov Instability -- Chapter70.Light/heavy converging Richtmyer-Meshkov instability in a conventional shock tube -- Chapter71.The Imploding Cylindrical Richtmyer-Meshkov Instability with a Two-Fluid Plasma Model -- Chapter72.Experimental Study on a Single-mode Interface Impacted by a Converging Shock -- Chapter73.The Richtmyer-Meshkov instability of a flat interface initiated by a perturbed shock -- Chapter74.A study of variable density mixing with reshock -- Chapter75.Wave Patterns in the Interaction of an Incident Shock with a Heavy Elliptic Gas Cylinder -- Chapter76.Reshocked Richtmyer-Meshkov instability: Numerical study on interface stretch and vortex cores characterization  -- Chapter77.Self-generated magnetic fields in the plasma Richtmyer-Meshkov instability -- Chapter78.The Evolution of a Square SF6 Gas Cylinder Impacted by a Converging Shock Wave -- Chapter79.Electron shock dynamics in the two-fluid plasma Richtmyer-Meshkov instability -- Chapter80.The Evolution of Concentration and Velocity-Fluctuations in the Richtmyer-Meshkov Instability -- Chapter81.Numerical Investigation of High-Temperature Effects in a Shock-Bubble Interaction. -- Chapter82.Transmitted wave of shock wave through various materials -- Chapter83.Numerical investigation of the interaction between a planar shock wave with a square bubble containing different gases -- Chapter84.Underwater Shock Wave by Explosion in a Closed Space -- Chapter85.Collision of underwater explosion with compressible porous wall -- Chapter86.Disturbance Waves behind the Shock Propagating through Non-uniform Gas -- Chapter87.Study on Mach stem shape of the asymmetric Mach reflection -- Chapter88.Experimental and numerical investigations of a shock wave propagation through a bifurcation -- Chapter89.The Reflection of Cylindrical Shock-Waves on Cylindrical Walls -- Chapter90.On InMR-TRR Transition on a Concave Cylindrical Reflector -- Chapter91.Reflection of a Planar Shock Wave over a Concave Double Wedge -- Chapter92.Shock Wave Reflections from a Plane of Symmetry -- Chapter93.The influence of short acting pressure driver pulses on the behavior of shock waves in micro shock tubes  -- Chapter94.Investigation of an Expansion Fan/Shock Wave Interaction between High Aspect Ratio Wedges -- Chapter95.Interaction of multiple cylindrical expanding shock waves -- Chapter96.Shock Interaction on a V-shaped Blunt Leading Edge -- Chapter97.Delayed Ventilation of Partially Confined DetonationProducts by Shock Reflection from a Convergent Nozzle Opening -- Chapter98.Geometrical perception of convex surface reflections -- Chapter99.Numerical Simulation of Supersonic/Hypersonic Flow for TSTO's Staging Separation -- Chapter100.Experimental Study of Normal Shock Wave-Isotropic Turbulence Interaction Using Counter-Driver Shock Tube -- Chapter101.Numerical Studies on Form of Weak Shock Reflection over Wedges -- Chapter102.Shock Wave Generation Method using High-Speed Jet -- Chapter103.Analytical Prediction of Mach Stem Height for Asymmetric Wedge Reflection in 2-D Steady Flows -- Chapter104.Upstream Pressure Induced MR-RR Shock Transitions -- Chapter105.Revisiting Shock Propagation in a Temperature Gradient -- Chapter106.On Hysteresis at Axisymmetric Curved Shock Reflection from an Axial Cylinder -- Chapter107.Singularity formation in the geometry of perturbed shocks -- Chapter108.A Gen.
330   $aThis is the first volume of a two volume set which presents the results of the 31st International Symposium on Shock Waves (ISSW31), held in Nagoya, Japan in 2017. It was organized with support from the International Shock Wave Institute (ISWI), Shock Wave Research Society of Japan, School of Engineering of Nagoya University, and other societies, organizations, governments and industry. The ISSW31 focused on the following areas: Blast waves, chemical reacting flows, chemical kinetics, detonation and combustion, ignition, facilities, diagnostics, flow visualization, spectroscopy, numerical methods, shock waves in rarefied flows, shock waves in dense gases, shock waves in liquids, shock waves in solids, impact and compaction, supersonic jet, multiphase flow, plasmas, magnetohyrdrodynamics, propulsion, shock waves in internal flows, pseudo-shock wave and shock train, nozzle flow, re-entry gasdynamics, shock waves in space, Richtmyer-Meshkov instability, shock/boundary layer interaction, shock/vortex interaction, shock wave reflection/interaction, shock wave interaction with dusty media, shock wave interaction with granular media, shock wave interaction with porous media, shock wave interaction with obstacles, supersonic and hypersonic flows, sonic boom, shock wave focusing, safety against shock loading, shock waves for material processing, shock-like phenomena, and shock wave education. These proceedings contain the papers presented at the symposium and serve as a reference for the participants of the ISSW 31 and individuals interested in these fields.
606   $aAerospace engineering
606   $aAstronautics
606   $aContinuum mechanics
606   $aFluid mechanics
606   $aChemistry, Physical and theoretical
606   $aComputational intelligence
606   $aAerospace Technology and Astronautics
606   $aContinuum Mechanics
606   $aEngineering Fluid Dynamics
606   $aPhysical Chemistry
606   $aComputational Intelligence
615  0$aAerospace engineering.
615  0$aAstronautics.
615  0$aContinuum mechanics.
615  0$aFluid mechanics.
615  0$aChemistry, Physical and theoretical.
615  0$aComputational intelligence.
615 14$aAerospace Technology and Astronautics.
615 24$aContinuum Mechanics.
615 24$aEngineering Fluid Dynamics.
615 24$aPhysical Chemistry.
615 24$aComputational Intelligence.
676   $a531.1133
702   $aSasoh$b A.$f1960-$4edt$4http://id.loc.gov/vocabulary/relators/edt
702   $aAoki$b Toshiyuki$4edt$4http://id.loc.gov/vocabulary/relators/edt
702   $aKatayama$b Masahide$4edt$4http://id.loc.gov/vocabulary/relators/edt
712 12$aInternational Symposium on Shock Waves.
906   $aBOOK
912   $a9910337634703321
996   $a31st International Symposium on Shock Waves 1$91925299
997   $aUNINA