Your search keyword '"Janni Yuval"' showing total 19 results

1. Neural‐Network Parameterization of Subgrid Momentum Transport in the Atmosphere

Author

Janni Yuval and Paul A. O’Gorman

Subjects

momentum parameterization, machine learning, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Attempts to use machine learning to develop atmospheric parameterizations have mainly focused on subgrid effects on temperature and moisture, but subgrid momentum transport is also important in simulations of the atmospheric circulation. Here, we use neural networks to develop a subgrid momentum transport parameterization that learns from coarse‐grained output of a high‐resolution atmospheric simulation in an idealized aquaplanet domain. We show that substantial subgrid momentum transport occurs due to convection. The neural‐network parameterization has skill in predicting momentum fluxes associated with convection, although its skill for subgrid momentum fluxes is lower compared to subgrid energy and moisture fluxes. The parameterization conserves momentum, and when implemented in the same atmospheric model at coarse resolution it leads to stable simulations and tends to reduce wind biases, although it over‐corrects for one configuration tested. Overall, our results show that it is challenging to predict subgrid momentum fluxes and that machine‐learning momentum parameterization gives promising results.

Published

2023

2. Stable machine-learning parameterization of subgrid processes for climate modeling at a range of resolutions

Author

Janni Yuval and Paul A. O’Gorman

Subjects

Science

Abstract

Machine learning has been used to represent small-scale processes, such as clouds, in atmospheric models but this can lead to instability in simulations of climate. Here, the authors demonstrate a use of machine learning in an atmospheric model that leads to stable simulations of climate at a range of grid spacings.

Published

2020

3. ClimSim: A large multi-scale dataset for hybrid physics-ML climate emulation.

Author

Sungduk Yu, Walter M. Hannah, Liran Peng, Jerry Lin, Mohamed Aziz Bhouri, Ritwik Gupta, Björn Lütjens, Justus C. Will, Gunnar Behrens, Julius Busecke, Nora Loose, Charles Stern, Tom Beucler, Bryce E. Harrop, Benjamin R. Hillman, Andrea M. Jenney, Savannah L. Ferretti, Nana Liu, Animashree Anandkumar, Noah D. Brenowitz, Veronika Eyring, Nicholas Geneva, Pierre Gentine, Stephan Mandt, Jaideep Pathak, Akshay Subramaniam, Carl Vondrick, Rose Yu, Laure Zanna, Tian Zheng, Ryan Abernathey, Fiaz Ahmed, David C. Bader, Pierre Baldi, Elizabeth A. Barnes, Christopher S. Bretherton, Peter M. Caldwell, Wayne Chuang, Yilun Han, Yu Huang, Fernando Iglesias-Suarez, Sanket R. Jantre, Karthik Kashinath, Marat Khairoutdinov, Thorsten Kurth, Nicholas J. Lutsko, Po-Lun Ma, Griffin Mooers, J. David Neelin, David A. Randall, Sara Shamekh, Mark Taylor, Nathan M. Urban, Janni Yuval, Guang Zhang, and Mike Pritchard

Published

2023

4. Neural General Circulation Models.

Author

Dmitrii Kochkov, Janni Yuval, Ian Langmore, Peter C. Norgaard, Jamie A. Smith, Griffin Mooers, James Lottes, Stephan Rasp 0001, Peter D. Düben, Milan Klöwer, Sam Hatfield, Peter W. Battaglia, Alvaro Sanchez-Gonzalez, Matthew Willson, Michael P. Brenner, and Stephan Hoyer

Published

2023

5. Improving Cardiovascular Disease Prediction Using Automated Coronary Artery Calcium Scoring from Existing Chest CTs.

Author

Noam Barda, Noa Dagan, Amos Stemmer, Janni Yuval, Eitan Bachmat, Eldad Elnekave, and Ran D. Balicer

Published

2022

6. Human-induced weakening of the Northern Hemisphere tropical circulation

Author

Rei Chemke and Janni Yuval

Subjects

Multidisciplinary

Published

2023

7. Climate-Invariant Machine Learning.

Author

Tom Beucler, Michael S. Pritchard, Janni Yuval, Ankitesh Gupta, Liran Peng, Stephan Rasp 0001, Fiaz Ahmed, Paul A. O'Gorman, J. David Neelin, Nicholas J. Lutsko, and Pierre Gentine

Published

2021

8. The intensification of winter mid-latitude storm tracks in the Southern Hemisphere

Author

Rei Chemke, Yi Ming, and Janni Yuval

Subjects

Physics - Atmospheric and Oceanic Physics, Atmospheric and Oceanic Physics (physics.ao-ph), FOS: Physical sciences, Environmental Science (miscellaneous), Social Sciences (miscellaneous)

Abstract

The strength of mid-latitude storm tracks shapes weather and climate phenomena in the extra-tropics, as these storm tracks control the daily to multi-decadal variability of precipitation, temperature and winds. By the end of this century, winter mid-latitude storms are projected to intensify in the Southern Hemisphere, with large consequences over the entire extra-tropics. Therefore, it is critical to be able to accurately assess the impacts of anthropogenic emissions on these storms, in order to improve societal preparedness for future changes. Here we show that current climate models severely underestimate the intensification in mid-latitude storm-tracks in recent decades. Specifically, the intensification obtained from reanalyses has already reached the model-projected end of the century intensification. The biased intensification is found to be linked to biases in the zonal flow. These results question the ability of climate models to accurately predict the future impacts of anthropogenic emissions in the Southern Hemisphere mid-latitudes., 3 figures in main, 8 figures in SI

Published

2022

9. Non‐Local Parameterization of Atmospheric Subgrid Processes With Neural Networks

Author

Peidong Wang, Janni Yuval, and Paul A. O’Gorman

Subjects

Physics - Atmospheric and Oceanic Physics, Global and Planetary Change, Atmospheric and Oceanic Physics (physics.ao-ph), FOS: Physical sciences, General Earth and Planetary Sciences, Environmental Chemistry, Physics::Atmospheric and Oceanic Physics

Abstract

Subgrid processes in global climate models are represented by parameterizations which are a major source of uncertainties in simulations of climate. In recent years, it has been suggested that machine-learning (ML) parameterizations based on high-resolution model output data could be superior to traditional parameterizations. Currently, both traditional and ML parameterizations of subgrid processes in the atmosphere are based on a single-column approach, which only use information from single atmospheric columns. However, single-column parameterizations might not be ideal since certain atmospheric phenomena, such as organized convective systems, can cross multiple grid boxes and involve slantwise circulations that are not purely vertical. Here we train neural networks (NNs) using non-local inputs spanning over 3$\times$3 columns of inputs. We find that including the non-local inputs improves the offline prediction of a range of subgrid processes. The improvement is especially notable for subgrid momentum transport and for atmospheric conditions associated with mid-latitude fronts and convective instability. Using an interpretability method, we find that the NN improvements partly rely on using the horizontal wind divergence, and we further show that including the divergence or vertical velocity as a separate input substantially improves offline performance. However, non-local winds continue to be useful inputs for parameterizating subgrid momentum transport even when the vertical velocity is included as an input. Overall, our results imply that the use of non-local variables and the vertical velocity as inputs could improve the performance of ML parameterizations, and the use of these inputs should be tested in online simulations in future work., Comment: 38 pages, 21 figures (7 figures in the main file)

Published

2022

10. Eddy Activity Response to Global Warming–Like Temperature Changes

Author

Yohai Kaspi and Janni Yuval

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Atmospheric circulation, Global warming, Climate change, 010502 geochemistry & geophysics, 01 natural sciences, Physics::Geophysics, Latitude, The arctic, Troposphere, Eddy, 13. Climate action, Climatology, Physics::Space Physics, Environmental science, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences

Abstract

Global warming projections show an anomalous temperature increase both at the Arctic surface and at lower latitudes in the upper troposphere. The Arctic amplification decreases the meridional temperature gradient, and simultaneously decreases static stability. These changes in the meridional temperature gradient and in the static stability have opposing effects on baroclinicity. The temperature increase at the upper tropospheric lower latitudes tends to increase the meridional temperature gradient and simultaneously increase static stability, which have opposing effects on baroclinicity as well. In this study, a dry idealized general circulation model with a modified Newtonian cooling scheme, which allows any chosen zonally symmetric temperature distribution to be simulated, is used to study the effect of Arctic amplification and lower-latitude upper-level warming on eddy activity. Due to the interplay between the static stability and meridional temperature gradient on atmospheric baroclinicity changes, and their opposing effect on atmospheric baroclinicity, it is found that both the Arctic amplification and lower-latitude upper-level warming could potentially lead to both decreases and increases in eddy activity, depending on the exact prescribed temperature modifications. Therefore, to understand the effect of global warming–like temperature trends on eddy activity, the zonally symmetric global warming temperature projections from state-of-the-art models are simulated. It is found that the eddy kinetic energy changes are dominated by the lower-latitude upper-level warming, which tends to weaken the eddy kinetic energy due to increased static stability. On the other hand, the eddy heat flux changes are dominated by the Arctic amplification, which tends to weaken the eddy heat flux at the lower levels.

Published

2020

11. Neural-network parameterization of subgrid momentum transport in the atmosphere

Author

Janni Yuval and Paul A. O'Gorman

Subjects

Nonlinear Sciences::Chaotic Dynamics, Physics::Fluid Dynamics, Atmosphere, Momentum (technical analysis), Artificial neural network, Moisture, Environmental science, Mechanics, Nonlinear Sciences::Cellular Automata and Lattice Gases, Physics::Atmospheric and Oceanic Physics, Mathematics::Numerical Analysis

Abstract

Attempts to use machine learning to develop atmospheric parameterizations have mainly focused on subgrid effects on temperature and moisture, but subgrid momentum transport is also important in sim...

Published

2021

12. Call for Papers on Machine Learning and Earth System Modeling

Author

Janni Yuval, Laure Zanna, Pierre Gentine, Jiwen Fan, and Michael S. Pritchard

Subjects

Earth system modeling, Computer science, business.industry, General Earth and Planetary Sciences, Artificial intelligence, business

Abstract

Contributions are invited to a new journal special collection on the use of new machine learning methodologies and applications of machine learning to Earth system modeling.

Published

2021

13. Use of neural networks for stable, accurate and physically consistent parameterization of subgrid atmospheric processes with good performance at reduced precision

Author

Paul A. O'Gorman, Janni Yuval, and Chris Hill

Subjects

Physical model, 010504 meteorology & atmospheric sciences, Artificial neural network, Computer science, FOS: Physical sciences, Replicate, Atmospheric model, 010502 geochemistry & geophysics, 01 natural sciences, Domain (software engineering), Atmospheric simulation, Numerical precision, Physics - Atmospheric and Oceanic Physics, Geophysics, Atmospheric and Oceanic Physics (physics.ao-ph), General Earth and Planetary Sciences, Granularity, Algorithm, 0105 earth and related environmental sciences

Abstract

A promising approach to improve climate-model simulations is to replace traditional subgrid parameterizations based on simplified physical models by machine learning algorithms that are data-driven. However, neural networks (NNs) often lead to instabilities and climate drift when coupled to an atmospheric model. Here we learn an NN parameterization from a high-resolution atmospheric simulation in an idealized domain by coarse graining the model equations and output. The NN parameterization has a structure that ensures physical constraints are respected, and it leads to stable simulations that replicate the climate of the high-resolution simulation with similar accuracy to a successful random-forest parameterization while needing far less memory. We find that the simulations are stable for a variety of NN architectures and horizontal resolutions, and that an NN with substantially reduced numerical precision could decrease computational costs without affecting the quality of simulations., 23 pages, 6 figures (2 figures in main file)

Published

2020

14. The Relation Between the Seasonal Changes in Jet Characteristics and the Pacific Midwinter Minimum in Eddy Activity

Author

Yohai Kaspi, H. Afargan, and Janni Yuval

Subjects

Jet (fluid), Geophysics, 010504 meteorology & atmospheric sciences, General Earth and Planetary Sciences, Eddy kinetic energy, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Geology, 0105 earth and related environmental sciences

Published

2018

15. Eddy Sensitivity to Jet Characteristics

Author

Janni Yuval and Yohai Kaspi

Subjects

Atmospheric Science, Jet (fluid), 010504 meteorology & atmospheric sciences, Atmospheric circulation, Astrophysics::High Energy Astrophysical Phenomena, Atmospheric sciences, 01 natural sciences, Physics::Fluid Dynamics, Atmosphere, Eddy, 0103 physical sciences, Environmental science, High Energy Physics::Experiment, Sensitivity (control systems), 010303 astronomy & astrophysics, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences

Abstract

The atmosphere exhibits two distinct types of jets: the thermally driven subtropical jet and the more poleward eddy-driven jet. Depending on location and season, these jets are often merged or separated, and their position, structure, and intensity strongly influence the eddy fields. Here, the authors study the sensitivity of eddies to changes in the jets’ amplitudes and positions in an idealized general circulation model. A modified Newtonian relaxation scheme that has a very short relaxation time for the mean state and a long relaxation time for eddies is used. This scheme makes it possible to obtain any zonally symmetric temperature distribution and is used to systematically modify the jets’ amplitudes and locations. It is found that eddies are more sensitive to changes in the amplitude of the eddy-driven jet than to changes in the amplitude of the subtropical jet. Furthermore, when the eddy-driven jet is shifted poleward, eddies tend to intensify. These results are tested for robustness in two different reference simulations: one resembling a situation where the subtropical and eddy-driven jets are nearly merged and one when they are separated.

Published

2018

16. The Effect of Vertical Baroclinicity Concentration on Atmospheric Macroturbulence Scaling Relations

Author

Yohai Kaspi and Janni Yuval

Subjects

Physics, Atmospheric Science, 010504 meteorology & atmospheric sciences, 010505 oceanography, Baroclinity, Lapse rate, Zonal and meridional, Atmospheric sciences, 01 natural sciences, Potential energy, Physics::Fluid Dynamics, Temperature gradient, Eddy, Newtonian fluid, Scaling, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences

Abstract

Motivated by the expectation that under global warming upper-level meridional temperature gradients will increase while lower-level temperature gradients will decrease, the relations between the vertical structure of baroclinicity and eddy fields are investigated. The sensitivity of eddies and the relation between the mean available potential energy and eddy quantities are studied for cases where the vertical structure of the lapse rate and meridional temperature gradient are modified. To investigate this systematically, an idealized general circulation model with a Newtonian cooling scheme that has a very short relaxation time for the mean state and a long relaxation time for eddies is used. This scheme allows for any chosen zonally mean state to be obtained with good precision. The results indicate that for similar change in the lapse rate or meridional temperature gradient, eddies are more sensitive to changes in baroclinicity where it is already large. Furthermore, when the vertical structure of the lapse rate or the meridional temperature gradient is modified, there is no universal linear relation between the mean available potential energy and eddy quantities.

Published

2017

17. Response of extreme precipitation to uniform surface warming in quasi-global aquaplanet simulations at high resolution

Author

William R. Boos, Janni Yuval, Paul A. O'Gorman, Ziwei Li, and Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences

Subjects

Deep convection, General Mathematics, General Circulation Model, Climatology, Surface warming, General Engineering, General Physics and Astronomy, High resolution, Tropics, Climate change, Environmental science, Precipitation

Abstract

Projections of precipitation extremes in simulations with global climate models are very uncertain in the tropics, in part because of the use of parameterizations of deep convection and model deficiencies in simulating convective organization. Here, we analyse precipitation extremes in high-resolution simulations that are run without a convective parameterization on a quasi-global aquaplanet. The frequency distributions of precipitation rates and precipitation cluster sizes in the tropics of a control simulation are similar to the observed distributions. In response to climate warming, 3 h precipitation extremes increase at rates of up to 9 % K − 1 in the tropics because of a combination of positive thermodynamic and dynamic contributions. The dynamic contribution at different latitudes is connected to the vertical structure of warming using a moist static stability. When the precipitation rates are first averaged to a daily timescale and coarse-grained to a typical global climate-model resolution prior to calculating the precipitation extremes, the response of the precipitation extremes to warming becomes more similar to what was found previously in coarse-resolution aquaplanet studies. However, the simulations studied here do not exhibit the high rates of increase of tropical precipitation extremes found in projections with some global climate models. This article is part of a discussion meeting issue ‘Intensification of short-duration rainfall extremes and implications for flash flood risks’.

Published

2021

18. Eddy Activity Sensitivity to Changes in the Vertical Structure of Baroclinicity

Author

Janni Yuval and Yohai Kaspi

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Atmospheric circulation, Baroclinity, Eddy covariance, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Eddy diffusion, Physics::Fluid Dynamics, Temperature gradient, Eddy, Newtonian fluid, Mean radiant temperature, Physics::Atmospheric and Oceanic Physics, Geology, 0105 earth and related environmental sciences

Abstract

The relation between the mean meridional temperature gradient and eddy fluxes has been addressed by several eddy flux closure theories. However, these theories give little information on the dependence of eddy fluxes on the vertical structure of the temperature gradient. The response of eddies to changes in the vertical structure of the temperature gradient is especially interesting since global circulation models suggest that as a result of greenhouse warming, the lower-tropospheric temperature gradient will decrease whereas the upper-tropospheric temperature gradient will increase. The effects of the vertical structure of baroclinicity on atmospheric circulation, particularly on the eddy activity, are investigated. An idealized global circulation model with a modified Newtonian relaxation scheme is used. The scheme allows the authors to obtain a heating profile that produces a predetermined mean temperature profile and to study the response of eddy activity to changes in the vertical structure of baroclinicity. The results indicate that eddy activity is more sensitive to temperature gradient changes in the upper troposphere. It is suggested that the larger eddy sensitivity to the upper-tropospheric temperature gradient is a consequence of large baroclinicity concentrated in upper levels. This result is consistent with a 1D Eady-like model with nonuniform shear showing more sensitivity to shear changes in regions of larger baroclinicity. In some cases, an increased temperature gradient at lower-tropospheric levels might decrease the eddy kinetic energy, and it is demonstrated that this might be related to the midwinter minimum in eddy kinetic energy observed above the northern Pacific.

Published

2016

19. Dynamics of elastic interactions in soft and biological matter

Author

Samuel A. Safran and Janni Yuval

Subjects

Physics, Propagation time, Time Factors, Viscosity, Relaxation (NMR), Cell Communication, Dissipation, Models, Biological, Elasticity, Quantitative Biology::Cell Behavior, Quantitative Biology::Subcellular Processes, Dipole, Classical mechanics, Liquid crystal, Dissipative system, Perpendicular, Thermodynamics, Cytoskeleton

Abstract

Cells probe their mechanical environment and can change the organization of their cytoskeletons when the elastic and viscous properties of their environment are modified. We use a model in which the forces exerted by small, contractile acto-myosin filaments (e.g., nascent stress fibers in stem cells) on the extracellular matrix are modeled as local force dipoles. In some cases, the strain field caused by these force dipoles propagates quickly enough so that only static elastic interactions need be considered. On the other hand, in the case of significant energy dissipation, strain propagation is slower and may be eliminated completely by the relaxation of the cellular cytoskeleton (e.g., by cross-link dissociation). Here, we consider several dissipative mechanisms that affect the propagation of the strain field in adhered cells and consider these effects on the interaction between force dipoles and their resulting mutual orientations. This is a first step in understanding the development of orientational (nematic) or layering (smectic) order in the cytoskeleton. We use the theory to estimate the propagation time of the strain fields over a cellular distance for different mechanisms and find that in some cases it can be of the order of seconds, thus competing with the cytoskeletal relaxation time. Furthermore, for a simple system of two force dipoles, we predict that in some cases the orientation of force dipoles might change significantly with time, e.g., for short times the dipoles exhibit parallel alignment while for later times they align perpendicularly.

Published

2013