Preface. 1 Introduction. 2 Earth and Planets. 2.1 Observational Overview. 2.1.1 Reversals.

2.1.2 Other Time-Variability. 2.2 Basic Equations and Parameters. 2.2.1 Anelastic and Boussinesq Equations.

2.2.2 Nondimensionalization. 2.3 Magnetoconvection. 2.3.1 Rotationor Magnetism Alone.

2.3.2 Rotation and Magnetism Together. 2.3.3 Weakversus Strong Fields. 2.3.

4 Oscillatory Convection Modes. 2.4 Taylor's Constraint. 2.4.1 Taylor's Original Analysis. 2.4.

2 Relaxation of Ro=E=0. 2.4.3 Taylor States versus Ekman States. 2.4.4 From Ekman States to Taylor States. 2.

4.5 Torsional Oscillations. 2.4.6 ±&-Dynamos. 2.4.7 Taylor's Constraint in the Anelastic Approximation.

2.5 Hydromagnetic Waves. 2.6 The Inner Core. 2.6.1 Stewartson Layers on C. 2.

6.2 Nonaxisymmetric Shear Layers on C. 2.6.3 Finite Conductivity of the Inner Core. 2.6.4 Rotation of the Inner Core.

2.7 Numerical Simulations. 2.8 Magnetic Instabilities. 2.9 Other Planets. 2.9.

1 Mercury, Venus and Mars. 2.9.2 Jupiter's Moons. 2.9.3 Jupiter and Saturn. 2.

9.4 Uranus and Neptune. 3 Differential Rotation Theory. 3.1 The Solar Rotation. 3.1.1 Torsional Oscillations.

3.1.2 Meridional Flow. 3.1.3 Ward's Correlation. 3.1.

4 Stellar Observations. 3.2 Angular Momentum Transport in Convection Zones. 3.2.1 The Taylor Number Puzzle. 3.2.

2 The ›-Effect. 3.2.3 The Eddy Viscosity Tensor. 3.2.4 Mean-Field Thermodynamics. 3.

3 Differential Rotation and Meridional Circulation for Solar-Type Stars. 3.4 Kinetic Helicity and the DIV-CURL-Correlation. 3.5 Overshoot Region and the Tachocline. 3.5.1 The NIRVANA Code.

3.5.2 Penetration into the Stable Layer. 3.5.3 A Magnetic Theory of the Solar Tachocline. 4 The Stellar Dynamo. 4.

1 The Solar-Stellar Connection. 4.1.1 The Phase Relation. 4.1.2 The Nonlinear Cycle. 4.

1.3 Parity. 4.1.4 Dynamo-related Stellar Observations. 4.1.5 The Flip-Flop Phenomenon.

4.1.6 More Cyclicities. 4.2 The ±-Tensor. 4.2.1 The Magnetic-Field Advection.

4.2.2 The Highly Anisotropic ±-Effect. 4.2.3 The Magnetic Quenching of the ±-Effect. 4.2.

4 Weak-Compressible Turbulence. 4.3 Magnetic-Diffusivity Tensor and ·-Quenching. 4.3.1 The Eddy Diffusivity Tensor. 4.3.

2 Sunspot Decay. 4.4 Mean-Field Stellar Dynamo Models. 4.4.1 The ±2-Dynamo. 4.4.

2 The ±&-Dynamo for Slow Rotation. 4.4.3 Meridional Flow Influence. 4.5 The Solar Dynamo. 4.5.

1 The Overshoot Dynamo. 4.5.2 The Advection-Dominated Dynamo. 4.6 Dynamos with Random ±. 4.6.

1 Aturbulence Model. 4.6.2 Dynamo Models with Fluctuating ±-Effect. 4.7 Nonlinear Dynamo Models. 4.7.

1 Malkus-Proctor Mechanism. 4.7.2 ±-Quenching. 4.7.3 Magnetic Saturation by Turbulent Pumping. 4.

7.4 ·-Quenching. 4.8 ›-Quenching and Maunder Minimum. 5 The Magnetorotational Instability (MRI). 5.1 Star Formation. 5.

1.1 Molecular Clouds. 5.1.2 The Angular Momentum Problem. 5.1.3 Turbulence and Planet Formation.

5.2 Stability of Differential Rotation in Hydrodynamics. 5.2.1 Combined Stability Conditions. 5.2.2 Sufficient Condition for Stability.

5.2.3 Numerical Simulations. 5.2.4 Vertical Shear. 5.3 Stability of Differential Rotation in Hydromagnetics.

5.3.1 Ideal MHD. 5.3.2 Baroclinic Instability. 5.4 Stability of Differential Rotation with Strong Hall Effect.

5.4.1 Criteria of Instability of Protostellar Disks. 5.4.2 Growth Rates. 5.5 Global Models.

5.5.1 A Spherical Model with Shear. 5.5.2 A Global Disk Model. 5.6 MRI of Differential Stellar Rotation.

5.6.1 T Tauri Stars (TTS). 5.6.2 The Ap-Star Magnetism. 5.6.

3 Decay of Differential Rotation. 5.7 Circulation-Driven Stellar Dynamos. 5.7.1 The Gailitis Dynamo. 5.7.

2 Meridiona.