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Ensemble approach in climate dynamics and nonequilibrium processes
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Jánosi I. M., T. Bíró, B. O. Lakatos, J. A. C. Gallas, and A. Szöllősi-Nagy: Changing water cycle under a warming climate: Tendencies in the Carpathian Basin, Climate 11, 118, 2023 | Bozóki, T., Sátori, G., Williams, E., Guha, A., Liu, Y., Steinbach, P., Leal, A., Herein, M., et al.: Day-to-day quantification of changes in global lightning activity based on Schumann resonances, Journal of Geophysical Research: Atmospheres, 128, e2023JD038557, 2023 | Kaszás B, T. Haszpra, M. Herein:: The snowball Earth transition in a climate model with drifting parameters: Splitting of the snapshot attractor, Chaos 29, 113102, 2019 | Jánosi D., Gy. Károlyi, and T. Tél: Climate change in mechanical systems: the snapshot view of parallel dynamical evolutions, Nonlinear Dynamics 106, 2781-2805, 2021 | Kadlecsik, Á., Á. Szeidemann, and M. Vincze: A simple approximation for the drift rates of rotating polygons on a free fluid surface, he European Physical Journal Special Topics, 232, 453–459, 2023 | Harlander, U., I. D. Borcia, M. Vincze, and C. Rodda: Probability distri- bution of extreme events in a baroclinic wave laboratory experiment, Fluids, 7, 274, 2022 | Bódai T., G. Drótos, M. Herein, F. Lunkeit, V. Lucarini: The Forced Response of the El Niño–Southern Oscillation–Indian Monsoon Teleconnection in Ensembles of Earth System Models,, J. Climate 33, 2163–2182,, 2020 | Gróf, A., Á. Szeidemann, and T. Tél: Challenges in developing an interdisciplinary teaching material on effects related to the Earth’s rotation, Can. J. Phys. 98, 719–725, 2020 | Haszpra T., M. Herein, and T. Bódai: Investigating ENSO and its teleconnections under climate change in an ensemble view – a new perspective, Earth Syst. Dynam., 11, 267–280, 2020 | Haszpra T., D. Topál, M. Herein: On the Time Evolution of the Arctic Oscillation and Related Wintertime Phenomena under Different Forcing Scenarios in an Ensemble Approach, J. Climate, 33, 3107–3124, 2020 | Gy. Károlyi, R. D. Prokaj, I. Scheuring, and T. Tél: Climate change in a conceptual atmosphere–phytoplankton model, Earth Syst. Dynam., 11, 603–615, 2020 | Tél T., T. Bódai, G. Drótos, T. Haszpra, M. Herein, B. Kaszás, M. Vincze: The theory of parallel climate realizations: A new framework of ensemble methods in a changing climate - an overview,, Journal of Statistical Physics 179, 1496–1530, 2020 | Tél T., M. Vincze and I. M. Jánosi: Vortices capturing matter: a classroom demonstration, Phys. Educ. 55, 015007, 2020 | Topál, D., Q. Ding, J. Mitchell, I. Baxter, M. Herein, T. Haszpra, R. Luo, and Q. Li: An Internal Atmospheric Process Determining Summertime Arctic Sea Ice Melting in the Next Three Decades: Lessons Learned from Five Large Ensembles and Multiple CMIP5 Clim, J. Climate 33, 7431–7454., 2020 | Haszpra T., D. Topál, M. Herein: Detecting forced changes in internal variability useing Large Ensembles: On hte use of methods baased on the "snapshot view", US Clivar Variations 18, 36-43, 2020 | Haszpra, T.: RePLaT-Chaos: a simple educational application to discover the chaotic nature of atmospheric advection, Atmosphere, 11, 29., 2020 | Jánosi, I. M., D. Silhavy, J. Tamás, and P. Csontos: Bulbous perennials precisely detect the length of winter and adjust flowering dates, New Phytologist, early view, 2020 | Jánosi, I. M., Á. Baki, M. W. Beims, and J. A. C. Gallas: Bottom-to-top decomposition of time-series by smoothness-controlled cubic splines: Uncovering distinct freezing-melting dynamics between the Arctic and the Antarctic,, Phys. Rev. Res. 2, accepted, 2020 | Károlyi Gy., R. D. Prokaj, I. Scheuring, and T. Tél: Climate change in a conceptual atmosphere–phytoplankton model, Earth Syst. Dynam., 11, 603–615, 2020 | Topál, D., Q. Ding, J. Mitchell, I. Baxter, M. Herein, T. Haszpra, R. Luo, and Q. Li: An Internal Atmospheric Process Determining Summertime Arctic Sea Ice Melting in the Next Three Decades: Lessons Learned from Five Large Ensembles and Multiple CMIP5 Clim, J. Climate 33, 7431–7454, 2020 | Jánosi, I. M., D. Silhavy, J. Tamás, and P. Csontos: Bulbous perennials precisely detect the length of winter and adjust flowering dates, New Phytologist 228, 1535-1547, 2020 | Jánosi, I. M., Á. Baki, M. W. Beims, and J. A. C. Gallas: Bottom-to-top decomposition of time-series by smoothness-controlled cubic splines: Uncovering distinct freezing-melting dynamics between the Arctic and the Antarctic,, Phys. Rev. Res. 2, 043040, 2020 | Bódai T., G. Drótos, K.-J. Ha, J.-Y. Lee, E.-S. Chung: Nonlinear forced change and nonergodicity: the case of ENSO-Indian Monsoon and global precipitation teleconnections, Front. Earth Sci. 8, 599785, 2021 | Jánosi D., T. Tél,: Chaos in conservative discrete-time systems subjected to parameter drift, Chaos 31, 033142, 2021 | Károlyi Gy., T. Tél: New features of doubly transient chaos: complexity of decay, J. Phys. Complex. 2. 035001, 2021 | Tél T: Chaos physics: what to teach in three lessons?, Phys. Educ. 56, 045002, 2021 | Tóth Á. L., T. Tél: Ball bouncing down rounded edge stairs: chaotic but tricky, Eur. J. Phys. 42, 035004, 2021 | Haszpra, T., Kiss, M., Izsa, É: Replat–Chaos-edu: an interactive educational tool for secondary school students for the illustration of the spreading of volcanic ash clouds, Journal of Physics: Conference Series, 1929(1), 012079, 2021 | Jánosi I. M., K. Medjdoub, and M. Vincze: Combined wind-solar electricity production potential over north-western Africa, Renewable and Sustainable Energy Reviews, 151, 111558, 2021 | Medjdoub, K., Jánosi, I. M., & Vincze, M: Laboratory experiments on the influence of stratification and a bottom sill on seiche damping., Ocean Science, 17, 997-1009, 2021 | Jánosi Imre: Klímaváltozás: hol tartunk most?, Magyar Kémikusok Lapja, Különszám, 2020. december, 1-4, 2020 | Pereszlényi Ádám, Száz Dénes, Jánosi Imre, Horváth Gábor: A zebrák léghűtőjének kísérleti cáfolata – Van-e légörvény sor a zebracsíkok fölött?, Természet Világa, 152(8), 348-35, 2021 | Jánosi D., T. Tél: Chaos in Hamiltonian systems subjected to parameter drift, Chaos 29, 121105, 2019 | Szeidemann Ákos, Gróf Andrea, Tél Tamás: Mozgás a forgó Földön: a ciklonoktól az Eötvös-mérlegig, Fizikai Szemle LXXI. évf. 7–8. szám, 2021 | Károlyi Gy., T. Tél: New features of doubly transient chaos: complexity of decay, J. Phys. Complex. 2. 035001, 2021 | Jánosi I. M., K. Medjdoub, and M. Vincze: Combined wind-solar electricity production potential over north-western Africa, Renewable and Sustainable Energy Reviews, 151, 111558, 2021 | Medjdoub K., Jánosi, I. M., & Vincze, M: Laboratory experiments on the influence of stratification and a bottom sill on seiche damping., Ocean Science, 17, 997-1009, 2021 | Pereszlényi Á., Száz D., Jánosi I., Horváth G.: A zebrák léghűtőjének kísérleti cáfolata – Van-e légörvény sor a zebracsíkok fölött?, Természet Világa, 152(8), 348-35, 2021 | Szeidemann Á., Gróf A., Tél T.: Mozgás a forgó Földön: a ciklonoktól az Eötvös-mérlegig, Fizikai Szemle LXXI. évf. 7–8. szám, 2021 | Vincze M, T. Bozóki, M. Herein, I. D. Borcia, U. Harlander, A. Horicsányi, A. Nyerges, C. Rodda, A. Pál & J. Pálfy: The Drake Passage opening from an experimental fluid dynamics point of view, Scientific Reports 11, 2021 | Jánosi D. and T. Tél,: Characterizing chaos in systems subjected to parameter drift, Phys. Rev. E 105 (Letters) L062202, 2022 | Omel'chenko O. E. and T. Tél: Focusing on transient chaos, J. Phys. Complex. 3 010201, 2022 | Lubensky T., T. Temesvári, I. Kondor, M. C. Angelini: Renormalization group in spin glasses,, in: Spin Glass Theory and Far Beyond - Replica Symmetry Breaking after 40 Years, eds: P. Charbonneau, E. Marinari, G. Parisi et al (World Scientific, Singapore), 2022 | Jánosi I. M., H. Kantz, J.A. Gallas, M. Vincze: Global coarse-grained mesoscale eddy statistics based on integrated kinetic energy and enstrophy correlations, Ocean Science 18, 1361-1375, 2022 | Ramírez-Ávila G. M., S. Depickère, I. M. Jánosi, and J. A. C. Gallas: Distribution of spiking and bursting in Rulkov’s neuron model, The European Physical Journal Special Topics 231, 319-328, 2022 | Jánosi I.M., A. Padash, J. A. C. Gallas, and H. Kantz: Passive tracer advection in the equatorial Pacific region: statistics, correlations and a model of fractional Brownian motion, Ocean Science 18, 307-320, 2022 | Rodda C., U. Harlander, M. Vincze: Jet stream variability in a polar warming scenario–a laboratory perspective, Weather and Climate Dynamics 3, 937–950, 2022 | Jánosi, I. M., Á. Baki, M. W. Beims, and J. A. C. Gallas: Bottom-to-top decomposition of time-series by smoothness-controlled cubic splines: Uncovering distinct freezing-melting dynamics between the Arctic and the Antarctic,, Phys. Rev. Res. 2, 043040, 2020 | Károlyi Gy., T. Tél: New features of doubly transient chaos: complexity of decay, J. Phys. Complex. 2. 035001, 2021 | Jánosi I.: Klímaváltozás: hol tartunk most?, Magyar Kémikusok Lapja, Különszám, 2020. december, 1-4, 2020 | Omel'chenko O. E. and T. Tél: Focusing on transient chaos, J. Phys. Complex. 3 010201, 2022 | Lubensky T., T. Temesvári, I. Kondor, M. C. Angelini: Renormalization group in spin glasses, in: Spin Glass Theory and Far Beyond - Replica Symmetry Breaking after 40 Years, eds: P. Charbonneau, E. Marinari, G. Parisi et al (World Scientific, Singapore) pp. 45-67, 2023 | Herein M., T. Tél, T. Haszpra: Where are the coexisting parallel climates? Large ensemble climate projections from the point of view of chaos theory, Chaos 33, 031104, 2023 | Tóth K., T. Tél: Quantum uncertainty: what to teach?, Phys. Educ. 58, 025019, 2023 | Jánosi I. M., H. Kantz, J. A. C. Gallas, and M. Vincze: Global coarse grained mesoscale eddy statistics based on integrated kinetic energy and enstrophy correlations, Ocean Science 18, 1361–1375, 2022 | Kaszás B.,, U. Feudel, and T. Tél: Leaking in history space: A way to analyze systems subjected to arbitrary driving, Chaos 28, 033612, 2018 | Kaszás B., U. Feudel, and T. Tél: Tipping phenomena in typical dynamical systems subjected to parameter drift, Scientific Reports 9, 8654(12), 2019 | Bozóki,T., L. Czelnai, A. Horicsányi, A. Nyerges, A. Pál, J. Pálfy, M. Vincze: Large-scale ocean circulation in the Southern Hemisphere with closed and open Drake Passage – A laboratory minimal model approach, Deep Sea Research Part II: Topical Studies in Oceanography 160, 16-24, 2019 | Haszpra, T.: Intricate features in the lifetime and deposition of atmospheric aerosol particles,, Chaos, 29, 071103, 2019 | Haszpra,T., M. Herein: Ensemble-based analysis of the pollutant spreading intensity induced by climate change, Scientific Reports, 9, 3896, 2019 | Jánosi, I.M., M. Vincze, G. Tóth, J.A. Gallas: Single super-vortex as a proxy for ocean surface flow fields,, Ocean Science, 15, 941-949, 2019 | Ramírez-Ávila G. M., I. M. Jánosi, and J. A. C. Gallas: Two-parameter areal scaling in the Hénon map, Europhysics Letters, 126, 20001, 2019 | Benczik, I.J.: Edutainment in the Magic Tower of Eger. Environmental awareness as a lifelong learning process, Journal of Applied Technical and Educational Sciences 9, 42-57, 2019 | Tél, T., L. Kadi, I. M. Janosi and M. Vincze: Experimental demonstration of the water-holding property of three-dimensional vortices, Europhysics Letters 123, 44001 (1-7), 2018 | Haszpra T: Intensification of large-scale stretching of atmospheric pollutant clouds due to climate change, J. Atmospheric Sciences 74, 4229-4240, 2017 |
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