In the 1980s, the paradigm of Fractal Geometry popularized the fact that the ubiquitous geostatistical power laws imply nondifferentiabilty of the corresponding fractal sets, fractal functions. The prototypical examples of such scaling have flucutations ?f which change with scale ?x accordng to laws of the form ?f f?x**H where H is the scaling exponent and f is flux. The famous Kolmorogov turbulence law is the special case where ?f = ?v for velocity fluctuations across a distance ?x with H = 1/3 and f = ?**1/3 where ? is the turbulent energy flux. Similarly, there is much evidence that topographic altitude fluctuations ?h are of the same form with ?f = ?h , H 1/2 and with f a fundamental flux field governing topography dynamics. In both ca...
In most geophysical flows, vortices (or eddies) of all sizes are observed. In 1941, Kolmogorov devis...
The land surfaces of Earth, of other planets and of moons show both scalespecific and scaling behav...
Many earth and environmental variables appear to scale as multiplicative (multifractal) processes wi...
In the 1980s, the paradigm of Fractal Geometry popularized the fact that the ubiquitous geostatistic...
International audienceStarting about thirty years ago, new ideas in nonlinear dynamics, particularly...
consequences of broken symmetry -here parity-is studied. In this model, turbulence is dominated by a...
International audienceThis paper shows how modern ideas of scaling can be used to model topography w...
International audience"Uncertainty and error growth are crosscutting geophysical issues. Since the "...
We analyse two classes of methods widely diffused in the geophysical community, especially for study...
In turbulent and other nonlinear geophysical processes, extreme variability is built up multiplicati...
International audienceOver wide ranges of scale, orographic processes have no obvious scale; this ha...
The interest in scale symmetries (scaling) in Geosciences has never lessened since the first pioneer...
International audienceDensity is a fundamental physical parameter involved in most geodynamics model...
This article examines fractals with reference to random models of natural surfaces, highlighting the...
In most geophysical flows, vortices (or eddies) of all sizes are observed. In 1941, Kolmogorov devis...
The land surfaces of Earth, of other planets and of moons show both scalespecific and scaling behav...
Many earth and environmental variables appear to scale as multiplicative (multifractal) processes wi...
In the 1980s, the paradigm of Fractal Geometry popularized the fact that the ubiquitous geostatistic...
International audienceStarting about thirty years ago, new ideas in nonlinear dynamics, particularly...
consequences of broken symmetry -here parity-is studied. In this model, turbulence is dominated by a...
International audienceThis paper shows how modern ideas of scaling can be used to model topography w...
International audience"Uncertainty and error growth are crosscutting geophysical issues. Since the "...
We analyse two classes of methods widely diffused in the geophysical community, especially for study...
In turbulent and other nonlinear geophysical processes, extreme variability is built up multiplicati...
International audienceOver wide ranges of scale, orographic processes have no obvious scale; this ha...
The interest in scale symmetries (scaling) in Geosciences has never lessened since the first pioneer...
International audienceDensity is a fundamental physical parameter involved in most geodynamics model...
This article examines fractals with reference to random models of natural surfaces, highlighting the...
In most geophysical flows, vortices (or eddies) of all sizes are observed. In 1941, Kolmogorov devis...
The land surfaces of Earth, of other planets and of moons show both scalespecific and scaling behav...
Many earth and environmental variables appear to scale as multiplicative (multifractal) processes wi...