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200 10$aKants Einleitung in die Rechtslehre von 1784 $eImmanuel Kants Rechtsbegriff in der Moralvorlesung "Mrongovius II" und der Naturrechtsvorlesung "Feyerabend" von 1784 sowie in der "Metaphysik der Sitten" von 1797 /$fPhilipp-Alexander Hirsch
210  1$aGo?ttingen :$cUniversita?tsverlag Go?ttingen,$d2012.
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330   $a1797 erscheint mit den Metaphysischen Anfangsgru?nden der Rechtslehre Immanuel Kants rechtsphilosophisches Hauptwerk. Nicht selten begegnet man daher der Auffassung, Kants Rechtsphilosophie entstamme im Wesentlichen seiner Spa?tphase und sei u?berdies nur schwer mit der kritischen Moralphilosophie der 1780er Jahre in Einklang zu bringen. Vor diesem Hintergrund widmet sich die vorliegende Untersuchung dem Vergleich des kantischen Rechtsbegriffs, wie er 1797 in der Einleitung in die Rechtslehre vorgestellt wird, mit Kants Ausfu?hrungen in den Vorlesungsnachschriften Moral-Mrongovius II und Naturrecht-Feyerabend aus dem Jahre 1784. Dabei kann nachgewiesen werden, dass der Rechtsbegriff von 1797 bereits 1784 ausgearbeitet war. Mehr noch: Es zeigt sich, dass Kants Rechtsbegriff nicht nur bereits in der Phase seiner kritischen Moralphilosophie vorlag, sondern vielmehr in einem Guss mit ihr konzipiert wurde und wie diese auf dem kritischen Freiheitsbegriff basiert.
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200 10$aFluid Mechanics$b[electronic resource]
210   $aNewburyport $cDover Publications$d2012
215   $a1 online resource (1587 p.)
225 1 $aDover Books on Physics
300   $aDescription based upon print version of record.
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327   $aDOVER BOOKS ON PHYSICS; Title Page; Dedication; Copyright Page; Table of Contents; Preface to the Dover Edition; Preface to the First Edition; Chapter 1 - Format and Fundamentals; 1.1 Introduction: A Survey of Fluid Mechanics; 1.2 Format of This Text; 1.3 Fundamental Quantities, Units; 1.4 Fundamental Idealizations; 1.5 Fundamental Coordinates; 1.6 Fundamental Kinematic Field; 1.7 Fundamental Descriptions: Lagrange versus Euler Description; References; Study Questions; Problems; Chapter 2 - Description of Fluids; 2.1 Introduction; 2.2 What Is a Fluid?; 2.3 Classification of Fluid Flows
327   $a2.4 Properties of FluidsReferences; Study Questions; Problems; Chapter 3 - A erohydrostatics; 3.1 Hydrostatics; 3.2 Uniform Acceleration; 3.3 Aerostatics; 3.4 Forces on Planar Bodies; 3.5 Hydrostatic Forces on Curved Bodies; 3.6 Buoyant Forces on Submerged Bodies; 3.7 Initial Stability of Floating and Submerged Ships; Study Questions; Problems; Chapter 4 - Differential Forms of Fluid Behavior; 4.1 Introduction; 4.2 General Property Balance; 4.3 The Differential Form of the Conservation of Mass; 4.4 The Differential Form of the Conservation of Linear Momentum
327   $a4.5 The Differential Form of the Conservation of Energy4.6 Air as an Incompressible and/or Inviscid Fluid; References; Study Questions; Problems; Chapter 5 - Integrated Forms of Fluid Behavior; 5.1 Introduction; 5.2 The Integral Form of the Conservation of Mass; 5.3 The Integral Form of the Conservation of Linear Momentum; 5.4 The Integral Form of the Conservation of Angular Momentum; 5.5 The Integral Form of the Conservation of Energy; Study Questions; Problems; Chapter 6 - Recapitulation; 6.1 Summary; 6.2 Special Forms of the Governing Equations; 6.3 Problem-Solving Technique
327   $a6.4 Examples of Problem-Solving TechniqueChapter 7 - Dimensional Analysis and Similitude; 7.1 Introduction; 7.2 Dimensional Analysis; 7.3 Buckingham Pi Theorem; 7.4 The Rayleigh Method; 7.5 Dimensionless Parameters; 7.6 Similitude; 7.7 Similarity Solutions and Transformations; 7.8 Geometric and Dynamic Similitude; 7.9 Modeling; 7.10 Drag; 7.11 Lift; 7.12 Vorticity Effect in Lift and Drag; References; Study Questions; Problems; Chapter 8 - Flow Visualization; 8.1 Introduction; 8.2 Equation of a Streamline; 8.3 Stream Function, ?; 8.4 Visualization Techniques; References; Study Questions
327   $aProblemsChapter 9 - Viscous Fluid Flows; 9.1 Introduction; 9.2 Rectilinear Flow Between Parallel Plates; 9.3 Suddenly Accelerated Flat Plate in a Viscous Fluid; 9.4 Rotational Viscous Flows; References; Study Questions; Problems; Chapter 10 - Laminar Pipe Flow; 10.1 Introduction; 10.2 Description of the Physical Phenomenon; 10.3 Equations of Motion for Laminar Flow in a Pipe; 10.4 The Moody Diagram; 10.5 Minor Losses; 10.6 Energy Equation for Real Fluid Flow in a Pipe; 10.7 Examples of Pipe Flow; References; Study Questions; Problems; Chapter 11 - Turbulent Pipe Flow; 11.1 Introduction
327   $a11.2 Detecting Turbulence
330   $a""The mixture of prose, mathematics, and beautiful illustrations is particularly well chosen."" - American ScientistThis monumental text by a noted authority in the field is specially designed to provide an orderly structured introduction to fluid mechanics, a field all too often seen by students as an amorphous mass of disparate equations instead of the coherent body of theory and application it should be. In addition, the book will help upgrade students' mathematical skills as they learn the fundamentals of fluid mechanics.The text presents a unified method of analysis that poses fluid mech
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