Normal mode tunes for linear coupled motion in six dimensional phase space. Informal report

“Dynamical mixing”, i.e. relaxation of a stellar phase space distribution through interaction with the mean gravitational field, is numerically investigated for a one-dimensional self-gravitating stellar gas. Qualitative results are presented in the form of a motion picture of the flow of phase points (representing homogeneous slabs of stars) in two-dimensional phase space.

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Geometric particle-in-cell methods for the Vlasov–Maxwell equations with spin effects

Journal of Plasma Physics ◽

10.1017/s0022377821000532 ◽

2021 ◽

Vol 87 (3) ◽

Author(s):

Nicolas Crouseilles ◽

Paul-Antoine Hervieux ◽

Yingzhe Li ◽

Giovanni Manfredi ◽

Yajuan Sun

Keyword(s):

Phase Space ◽

Maxwell Equations ◽

Stimulated Raman Scattering ◽

Extended Phase ◽

Five Dimensions ◽

Particle In Cell ◽

Spin Effects ◽

Dimensional Phase Space ◽

Spin Polarized ◽

Underdense Plasma

We propose a numerical scheme to solve the semiclassical Vlasov–Maxwell equations for electrons with spin. The electron gas is described by a distribution function $f(t,{\boldsymbol x},{{{\boldsymbol p}}}, {\boldsymbol s})$ that evolves in an extended 9-dimensional phase space $({\boldsymbol x},{{{\boldsymbol p}}}, {\boldsymbol s})$ , where $\boldsymbol s$ represents the spin vector. Using suitable approximations and symmetries, the extended phase space can be reduced to five dimensions: $(x,{{p_x}}, {\boldsymbol s})$ . It can be shown that the spin Vlasov–Maxwell equations enjoy a Hamiltonian structure that motivates the use of the recently developed geometric particle-in-cell (PIC) methods. Here, the geometric PIC approach is generalized to the case of electrons with spin. Total energy conservation is very well satisfied, with a relative error below $0.05\,\%$ . As a relevant example, we study the stimulated Raman scattering of an electromagnetic wave interacting with an underdense plasma, where the electrons are partially or fully spin polarized. It is shown that the Raman instability is very effective in destroying the electron polarization.

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A three-dimensional phase space dynamical model of the Earth’s radiation belt

10.1063/1.51550 ◽

1996 ◽

Author(s):

D. M. Boscher ◽

T. Beutier ◽

S. Bourdarie

Keyword(s):

Phase Space ◽

Radiation Belt ◽

Three Dimensional ◽

Dynamical Model ◽

Dimensional Phase Space ◽

Earth’S Radiation Belt

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Dynamical properties and extremes of Northern Hemisphere climate fields over the past 60 years

Nonlinear Processes in Geophysics ◽

10.5194/npg-24-713-2017 ◽

2017 ◽

Vol 24 (4) ◽

pp. 713-725 ◽

Cited By ~ 20

Author(s):

Davide Faranda ◽

Gabriele Messori ◽

M. Carmen Alvarez-Castro ◽

Pascal Yiou

Keyword(s):

Phase Space ◽

Sea Level ◽

Northern Hemisphere ◽

Atmospheric Dynamics ◽

Complex Nature ◽

Human Welfare ◽

Sea Level Pressure ◽

Level Pressure ◽

Dimensional Phase Space ◽

Dynamical Properties

Abstract. Atmospheric dynamics are described by a set of partial differential equations yielding an infinite-dimensional phase space. However, the actual trajectories followed by the system appear to be constrained to a finite-dimensional phase space, i.e. a strange attractor. The dynamical properties of this attractor are difficult to determine due to the complex nature of atmospheric motions. A first step to simplify the problem is to focus on observables which affect – or are linked to phenomena which affect – human welfare and activities, such as sea-level pressure, 2 m temperature, and precipitation frequency. We make use of recent advances in dynamical systems theory to estimate two instantaneous dynamical properties of the above fields for the Northern Hemisphere: local dimension and persistence. We then use these metrics to characterize the seasonality of the different fields and their interplay. We further analyse the large-scale anomaly patterns corresponding to phase-space extremes – namely time steps at which the fields display extremes in their instantaneous dynamical properties. The analysis is based on the NCEP/NCAR reanalysis data, over the period 1948–2013. The results show that (i) despite the high dimensionality of atmospheric dynamics, the Northern Hemisphere sea-level pressure and temperature fields can on average be described by roughly 20 degrees of freedom; (ii) the precipitation field has a higher dimensionality; and (iii) the seasonal forcing modulates the variability of the dynamical indicators and affects the occurrence of phase-space extremes. We further identify a number of robust correlations between the dynamical properties of the different variables.

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Effects of Vegetation and Topography on the Boundary Layer Structure above the Amazon Forest

Journal of the Atmospheric Sciences ◽

10.1175/jas-d-20-0063.1 ◽

2020 ◽

Vol 77 (8) ◽

pp. 2941-2957

Author(s):

Marcelo Chamecki ◽

Livia S. Freire ◽

Nelson L. Dias ◽

Bicheng Chen ◽

Cléo Quaresma Dias-Junior ◽

...

Keyword(s):

Boundary Layer ◽

Phase Space ◽

Vertical Structure ◽

Layer Structure ◽

Roughness Sublayer ◽

Large Contribution ◽

Amazon Forest ◽

Two Dimensional ◽

Dimensional Phase Space ◽

Field Campaigns

Abstract Observational data from two field campaigns in the Amazon forest were used to study the vertical structure of turbulence above the forest. The analysis was performed using the reduced turbulent kinetic energy (TKE) budget and its associated two-dimensional phase space. Results revealed the existence of two regions within the roughness sublayer in which the TKE budget cannot be explained by the canonical flat-terrain TKE budgets in the canopy roughness sublayer or in the lower portion of the convective ABL. Data analysis also suggested that deviations from horizontal homogeneity have a large contribution to the TKE budget. Results from LES of a model canopy over idealized topography presented similar features, leading to the conclusion that flow distortions caused by topography are responsible for the observed features in the TKE budget. These results support the conclusion that the boundary layer above the Amazon forest is strongly impacted by the gentle topography underneath.

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