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27 results on '"Gritsun, Andrey"'

1. Heterogeneity of the Attractor of the Lorenz '96 Model: Lyapunov Analysis, Unstable Periodic Orbits, and Shadowing Properties

Author

Maiocchi, Chiara Cecilia, Lucarini, Valerio, Gritsun, Andrey, and Sato, Yuzuru

Subjects
Nonlinear Sciences - Chaotic Dynamics, Condensed Matter - Statistical Mechanics, Physics - Atmospheric and Oceanic Physics, Physics - Computational Physics, Physics - Fluid Dynamics
Abstract

The predictability of weather and climate is strongly state-dependent: special and extremely relevant atmospheric states like blockings are associated with anomalous instability. Indeed, typically, the instability of a chaotic dynamical system can vary considerably across its attractor. Such an attractor is in general densely populated by unstable periodic orbits that can be used to approximate any forward trajectory through the so-called shadowing. Dynamical heterogeneity can lead to the presence of unstable periodic orbits with different number of unstable dimensions. This phenomenon - unstable dimensions variability - implies a serious breakdown of hyperbolicity and has considerable implications in terms of the structural stability of the system and of the possibility to describe accurately its behaviour through numerical models. As a step in the direction of better understanding the properties of high-dimensional chaotic systems, we provide here an extensive numerical study of the dynamical heterogeneity of the Lorenz '96 model in a parametric configuration leading to chaotic dynamics. We show that the detected variability in the number of unstable dimensions is associated with the presence of many finite-time Lyapunov exponents that fluctuate about zero also when very long averaging times are considered. The transition between regions of the attractor with different degrees of instability comes with a significant drop of the quality of the shadowing. By performing a coarse graining based on the shadowing unstable periodic orbits, we can characterize the slow fluctuations of the system between regions featuring, on the average, anomalously high and anomalously low instability. In turn, such regions are associated, respectively, with states of anomalously high and low energy, thus providing a clear link between the microscopic and thermodynamical properties of the system., Comment: 28 pages, 11 figures, final accepted version

Published
2023

2. Decomposing the Dynamics of the Lorenz 1963 model using Unstable Periodic Orbits: Averages, Transitions, and Quasi-Invariant Sets

Author

Maiocchi, Chiara Cecilia, Lucarini, Valerio, and Gritsun, Andrey

Subjects
Nonlinear Sciences - Chaotic Dynamics, Condensed Matter - Statistical Mechanics, Physics - Computational Physics, Physics - Data Analysis, Statistics and Probability
Abstract

Unstable periodic orbits (UPOs) are a valuable tool for studying chaotic dynamical systems, as they allow one to distill their dynamical structure. We consider here the Lorenz 1963 model with the classic parameters' value. We investigate how a chaotic trajectory can be approximated using a complete set of UPOs up to symbolic dynamics' period 14. At each instant, we rank the UPOs according to their proximity to the position of the orbit in the phase space. We study this process from two different perspectives. First, we find that longer period UPOs overwhelmingly provide the best local approximation to the trajectory. Second, we construct a finite-state Markov chain by studying the scattering of the orbit between the neighbourhood of the various UPOs. Each UPO and its neighbourhood are taken as a possible state of the system. Through the analysis of the subdominant eigenvectors of the corresponding stochastic matrix we provide a different interpretation of the mixing processes occurring in the system by taking advantage of the concept of quasi-invariant sets., Comment: 13 pages, 7 figures

Published
2021
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3. Scalability of the INM RAS Earth System Model

Author

Tarasevich, Maria, Sakhno, Andrey, Blagodatskikh, Dmitry, Fadeev, Rostislav, Volodin, Evgeny, Gritsun, Andrey, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Voevodin, Vladimir, editor, Sobolev, Sergey, editor, Yakobovskiy, Mikhail, editor, and Shagaliev, Rashit, editor

Published
2023
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5. A New Mathematical Framework for Atmospheric Blocking Events

Author

Lucarini, Valerio and Gritsun, Andrey

Subjects
Physics - Atmospheric and Oceanic Physics, Condensed Matter - Statistical Mechanics, Nonlinear Sciences - Chaotic Dynamics, Physics - Fluid Dynamics, Physics - Geophysics
Abstract

We use a simple yet Earth-like atmospheric model to propose a new framework for understanding the mathematics of blocking events. Analysing error growth rates along a very long model trajectory, we show that blockings are associated with conditions of anomalously high instability of the atmosphere. Additionally, the lifetime of a blocking is positively correlated with the intensity of such an anomaly, against intuition. In the case of Atlantic blockings, predictability is especially reduced at the onset and decay of the blocking, while a relative increase of predictability is found in the mature phase, while the opposite holds for Pacific blockings, for which predictability is lowest in the mature phase. We associate blockings to a specific class of unstable periodic orbits (UPOs), natural modes of variability that cover the attractor of the system. The UPOs differ substantially in terms of instability, which explains the diversity of the atmosphere in terms predictability. The UPOs associated to blockings are indeed anomalously unstable, which leads to them being rarely visited. The onset of a blocking takes place when the trajectory of the system hops into the neighbourhood of one of these special UPOs. The decay takes place when the trajectory hops back to the neighbourhood of usual, less unstable UPOs associated with zonal flow. This justifies the classical Markov chains-based analysis of transitions between weather regimes. The existence of UPOs differing in the dimensionality of their unstable manifold indicates a very strong violation of hyperbolicity in the model, which leads to a lack of structural stability. We propose that this is could be a generic feature of atmospheric models and might be a fundamental cause behind difficulties in representing blockings for the current climate and uncertainties in predicting how their statistics will change as a result of climate change., Comment: 39 pages, 14 figures; improved discussion and referencing; several new/updated figures

Published
2019
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6. Fluctuations, Response, and Resonances in a Simple Atmospheric Model

Author

Gritsun, Andrey and Lucarini, Valerio

Subjects
Physics - Atmospheric and Oceanic Physics, Condensed Matter - Statistical Mechanics, Nonlinear Sciences - Chaotic Dynamics, Physics - Fluid Dynamics
Abstract

We study the response of a simple quasi-geostrophic barotropic model of the atmosphere to various classes of perturbations affecting its forcing and its dissipation using the formalism of the Ruelle response theory. We investigate the geometry of such perturbations by constructing the covariant Lyapunov vectors of the unperturbed system and discover in one specific case - orographic forcing - a substantial projection of the forcing onto the stable directions of the flow. This results into a resonant response shaped as a Rossby-like wave that has no resemblance to the unforced variability in the same range of spatial and temporal scales. Such a climatic surprise corresponds to a violation of the fluctuation-dissipation theorem, in agreement with the basic tenets of nonequilibrium statistical mechanics. The resonance can be attributed to a specific group of rarely visited unstable periodic orbits of the unperturbed system. Our results reinforce the idea of using basic methods of nonequilibrium statistical mechanics and high-dimensional chaotic dynamical systems to approach the problem of understanding climate dynamics., Comment: 20 pages, 12 figures; final revision of the paper

Published
2016
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9. A new tool for studying seasonality and spatio-temporal structure of ENSO cycles in data and ESM simulations.

Author

Mukhin, Dmitry, Safonov, Semen, Gavrilov, Andrey, Gritsun, Andrey, and Feigin, Alexander

Subjects
SOUTHERN oscillation, EL Nino, ENTHALPY
Abstract

In this work, we present a new diagnostic tool for El Niño Southern Oscillation (ENSO) simulations in Earth System Models (ESMs) based on the analysis of upper ocean heat content data. It allows us to identify the seasonally dependent structure of temperature anomalies in the equatorial Pacific Ocean in the form of a dominant spatio-temporal pattern. We demonstrate the results of applying a tool to analysis of real data as well as climate simulations in two versions of the Institute of Numerical Mathematics ESM. We find that the latest version of the model, with improved parameterizations of clouds, large-scale condensation, and aerosols, provides significantly better reproduction of ENSO-related structure of anomalies, as well as the phase locking of ENSO to the annual cycle. We recommend to use the tool for diagnostic analysis of ESMs regarding simulation of climate phenomena with strong seasonality. [ABSTRACT FROM AUTHOR]

Published
2024
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10. ENSO phase locking, asymmetry and predictability in the INMCM Earth system model.

Author

Seleznev, Aleksei F., Gavrilov, Andrey S., Mukhin, Dmitry N., Gritsun, Andrey S., and Volodin, Evgenii M.

Subjects
EL Nino, SOUTHERN oscillation, ATMOSPHERIC models, ENTHALPY, ORTHOGONAL functions, MODES of variability (Climatology)
Abstract

Advanced numerical climate models are known to exhibit biases in simulating some features of El Niño–Southern Oscillation (ENSO), which is a key mode of interannual climate variability. In this study we analyze how two fundamental features of observed ENSO – asymmetry between hot and cold states and phase-locking to the annual cycle – are reflected in two different versions of the INMCM Earth system model (state-of-the-art Earth system model participating in the Coupled Model Intercomparison Project). We identify the above ENSO features using the conventional empirical orthogonal functions (EOF) analysis, which is applied to both observed and simulated upper ocean heat content (OHC) data in the tropical Pacific. We obtain that the observed tropical Pacific OHC variability is described well by two leading EOF-modes, which roughly reflect the fundamental recharge-discharge mechanism of ENSO. These modes exhibit strong seasonal cycles associated with ENSO phase locking while the revealed nonlinear dependencies between amplitudes of these cycles reflect ENSO asymmetry.We also assess and compare the predictability of observed and simulated ENSO based on linear inverse modelling. We find that the improved INMCM6 model has significant benefits in simulating described features of observed ENSO as compared with the previous INMCM5 model. The improvements of the INMCM6 model providing such benefits are discussed. We argue that proper cloud parameterization scheme is crucial for accurate simulation of ENSO dynamics with numerical climate models. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Climate response of linear and quadratic functionals using the fluctuation-dissipation theorem

Author

Gritsun, Andrey, Branstator, Grant, and Majda, Andrew

Subjects
Atmospheric circulation -- Models, Precipitation (Meteorology) -- Observations, Quadratic functions -- Evaluation, Atmospheric research, Earth sciences, Science and technology
Abstract

A generalization of the fluctuation-dissipation theorem (FDT) that allows generation of linear response operators that estimate the response of functionals of system state variables is tested for a system defined by an atmospheric general circulation model (AGCM). A sketch of the proof of this generalization is provided, followed by comparison of response estimates based on the theory and actual responses of the AGCM for various idealized anomalous equatorial heat sources. Tested response quantities include precipitation, variances of bandpass and low-pass streamfunction, and momentum and heat fluxes. The solutions from the FDT operators are very similar to the AGCM solutions in terms of structure while overestimating response amplitudes by about 20%. As an example of an application of such response operators, the FDT operator that estimates the response of bandpass upper-tropospheric streamfunction variance is used to find the most efficient means of disturbing the Atlantic storm tracks by tropical heating. The results of the study suggest that the generalized FDT is an attractive method for systematically studying response attributes of the climate system that are of interest to climate scientists and society.

Published
2008

15. Climate response using a three-dimensional operator based on the fluctuation-dissipation theorem

Author

Gritsun, Andrey and Branstator, Grant

Subjects
Northern Hemisphere -- Environmental aspects, Atmospheric circulation -- Models, Atmospheric research, Earth sciences, Science and technology
Abstract

The fluctuation-dissipation theorem (FDT) states that for systems with certain properties it is possible to generate a linear operator that gives the response of the system to weak external forcing simply by using covariances and lag-covariances of fluctuations of the undisturbed system. This paper points out that the theorem can be shown to hold for systems with properties very close to the properties of the earth's atmosphere. As a test of the theorem's applicability to the atmosphere, a three-dimensional operator for steady responses to external forcing is constructed for data from an atmospheric general circulation model (AGCM). The response of this operator is then compared to the response of the AGCM for various heating functions. In most cases, the FDT-based operator gives three-dimensional responses that are very similar in structure and amplitude to the corresponding GCM responses. The operator is also able to give accurate estimates for the inverse problem in which one derives the forcing that will produce a given response in the AGCM. In the few cases where the operator is not accurate, it appears that the fact that the operator was constructed in a reduced space is at least partly responsible. As an example of the potential utility of a response operator with the accuracy found here, the FDT-based operator is applied to a problem that is difficult to solve with an AGCM. It is used to generate an influence function that shows how well heating at each point on the globe excites the AGCM's Northern Hemisphere annular mode (NAM). Most of the regions highlighted by this influence function, including the Arctic and tropical Indian Ocean, are verified by AGCM solutions as being effective locations for stimulating the NAM.

Published
2007

16. Decomposing the dynamics of the Lorenz 1963 model using unstable periodic orbits: Averages, transitions, and quasi-invariant sets.

Author

Maiocchi, Chiara Cecilia, Lucarini, Valerio, and Gritsun, Andrey

Subjects
LORENZ equations, SYMBOLIC dynamics, STOCHASTIC matrices, MARKOV processes, PHASE space, DYNAMICAL systems
Abstract

Unstable periodic orbits (UPOs) are a valuable tool for studying chaotic dynamical systems, as they allow one to distill their dynamical structure. We consider here the Lorenz 1963 model with the classic parameters' value. We investigate how a chaotic trajectory can be approximated using a complete set of UPOs up to symbolic dynamics' period 14. At each instant, we rank the UPOs according to their proximity to the position of the orbit in the phase space. We study this process from two different perspectives. First, we find that longer period UPOs overwhelmingly provide the best local approximation to the trajectory. Second, we construct a finite-state Markov chain by studying the scattering of the orbit between the neighborhood of the various UPOs. Each UPO and its neighborhood are taken as a possible state of the system. Through the analysis of the subdominant eigenvectors of the corresponding stochastic matrix, we provide a different interpretation of the mixing processes occurring in the system by taking advantage of the concept of quasi-invariant sets. [ABSTRACT FROM AUTHOR]

Published
2022
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20. Simulation of the modern climate using the INM-CM48 climate model

Author

Volodin, Evgenii M., primary, Mortikov, Evgeny V., additional, Kostrykin, Sergey V., additional, Galin, Vener Ya., additional, Lykossov, Vasily N., additional, Gritsun, Andrey S., additional, Diansky, Nikolay A., additional, Gusev, Anatoly V., additional, Iakovlev, Nikolay G., additional, Shestakova, Anna A., additional, and Emelina, Svetlana V., additional

Published
2018
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