[0] Berloff, P. and G. Sutyrin, 2024: Baroclinic vortex pulsars in unstable westward flows. Physica D, submitted.
[0] Meacham, J., and P. Berloff, 2024: Clustering of buoyant tracer in quasigeostrophic coherent structures. J. Fluid Mech., submitted.
[0] Davies, J., I. Shevchenko, P. Berloff, and G. Sutyrin, 2024: Linear instability and weakly nonlinear effects in eastward dipoles. Physica D, 460, 134068.
[1] Meacham, J., and P. Berloff, 2024: Clustering as a mechanism for enhanced reaction of buoyant species. J. Marine Systems, 243, 103952.
[2] Davies, J., G. Sutyrin, M. Crowe, and P. Berloff, 2023b: Deformation and destruction of north-eastward drifting dipoles. Phys. Fluids, 35, 116601.
[3] Shevchenko, I., and P. Berloff, 2023b: On a probabilistic evolutionary approach to ocean modelling: From Lorenz-63 to idealized ocean models. Ocean Modelling, 186, 102278.
[4] Shevchenko, I., and P. Berloff, 2023a: A hyper-parameterization method for comprehensive ocean models: Advection of the image point. Ocean Modelling, 184, 102208.
[5] Meacham, J., and P. Berloff, 2023: On clustering of floating tracers in random velocity fields. J. Adv. Model. Earth Sys., 15, e2022MS003484.
[6] Kurashina, R., and P. Berloff, 2023: Low-frequency variability enhancement of the midlatitude climate in an eddy-resolving, coupled ocean-atmosphere model. Part II: Ocean mechanisms. Climate Dynamics, doi:10.1007/s00382-023-06767-x.
[7] Kurashina, R., and P. Berloff, 2023: Low-frequency variability enhancement of the midlatitude climate in an eddy-resolving, coupled ocean-atmosphere model. Part I: Anatomy. Climate Dynamics, doi:10.1007/s00382-023-06782-y.
[8] Davies, J., G, Sutyrin, and P. Berloff, 2023a: On the spontaneous symmetry breaking of eastward propagating dipoles. Phys. Fluids, 35, 041707.
[9] Lu, Y., I. Kamenkovich, and P. Berloff, 2022: Properties of the lateral mesoscale eddy-induced transport in a high-resolution model: Beyond the flux-gradient relation. J. Phys. Ocean., 52, 3273--3295.
[10] Shevchenko, I., and P. Berloff, 2022: A method for preserving nominally-resolved flow patterns in low-resolution ocean simulations: Constrained dynamics. Ocean Modelling, 178, 102098.
[11] Ryzhov, E., and P. Berloff, 2022: On transport tensor of dynamically unresolved oceanic mesoscale eddies. J. Fluid Mech., 939, A7.
[12] Haigh, M., and P. Berloff, 2022: On the stability of tracer simulations with opposite-signed diffusivities. J. Fluid Mech., 937, R3.
[13] Shevchenko, I., and P. Berloff, 2022: A method for preserving nominally-resolved flow patterns in low-resolution ocean simulations: Dynamical system reconstruction. Ocean Modelling, 170, 101939.
[14] Shevchenko, I., and P. Berloff, 2021: On a minimum set of equations for parameterisations in comprehensive ocean circulation models. Ocean Modelling, 168, 101913.
[15] Haigh, M., and P. Berloff, 2021: On co-existing diffusive and anti-diffusive tracer transport by oceanic mesoscale eddies. Ocean Modelling, 168, 101909.
[16] Agarwal, N., D. Kondrashov, P. Dueben, E. Ryzhov, and P. Berloff, 2021: A comparison of data-driven approaches to build low-dimensional ocean models. J. Adv. Model. Earth Sys., 13, e2021MS002537.
[17] Agarwal, N., E. Ryzhov, D. Kondrashov, and P. Berloff, 2021: Correlation-based flow decomposition and statistical analysis of the eddy forcing. J. Fluid Mech., 924, A5.
[18] Haigh, M., L. Sun, J. McWilliams, and P. Berloff, 2021b: On eddy transport in the ocean. Part II: The advection tensor. Ocean Modelling, 165, 101845.
[19] Haigh, M., L. Sun, J. McWilliams, and P. Berloff, 2021a: On eddy transport in the ocean. Part I: The diffusion tensor. Ocean Modelling, 164, 101831.
[20] Berloff, P., E. Ryzhov, and I. Shevchenko, 2021: On dynamically unresolved oceanic mesoscale motions. J. Fluid Mech., 920, A41.
[21] Sun, L., M. Haigh, I. Shevchenko, P. Berloff, and I. Kamenkovich, 2021: On non-uniqueness of the mesoscale eddy diffusivity. J. Fluid Mech., 920, A32.
[22] Kurashina, R., P. Berloff, and I. Shevchenko, 2021: Western boundary layer nonlinear control of the oceanic gyres. J. Fluid Mech., 918, A43.
[23] Shevchenko, I., and P. Berloff, 2021: A method for preserving large-scale flow patterns in low-resolution ocean simulations. Ocean Modelling, 161, 101795.
[24] Kamenkovich, I., P. Berloff, M. Haigh, L. Sun, and Y. Lu, 2021: Complexity of mesoscale eddy diffusivity in the ocean. Geophys. Res. Lett., 48, e2020GL091719.
[25] Davies, J., H. Khatri, and P. Berloff, 2021: Linear stability analysis for flows over sinusoidal bottom topography. J. Fluid Mech., 911, A33, doi:10.1017/jfm.2020.1082.
[26] Ryzhov, E., D. Kondrashov, N. Agarwal, J. McWilliams, and P. Berloff, 2020: On data-driven induction of the low-frequency variability in a coarse-resolution ocean model. Ocean Modelling, 153, 101664.
[27] Stepanov, D., E. Ryzhov, P. Berloff, and K. Koshel, 2020: Floating tracer clustering in divergent random flows modulated by an unsteady mesoscale ocean field. Geophys. Astrophys. Fluid Dyn., doi: 10.1080/03091929.2020.1786551.
[28] Kondrashov, D., E. Ryzhov, and P. Berloff, 2020: Data-adaptive harmonic analysis of oceanic waves and turbulent flows. Chaos, 30, 061105.
[29] Haigh, M., L. Sun, I. Shevchenko, and P. Berloff, 2020: Tracer-based estimates of eddy-induced diffusivities. Deep-Sea Research, 160, 103264.
[30] Haigh, M., and P. Berloff, 2020: Rossby waves and zonal momentum redistribution induced by localised forcing in the rotating shallow-water model. J. Fluid Mech., 885, A43.
[31] Stepanov, D., E. Ryzhov, P. Zagumennov, P. Berloff, and K. Koshel, 2020: Clustering of floating tracer due to mesoscale vortex and submesoscale fields. Geophys. Res. Lett., 48, e2019GL086504.
[32] Koshel, K., D. Stepanov, E. Ryzhov, P. Berloff, and V. Klyatskin, 2019: Clustering of floating tracers in weakly divergent velocity fields. Physical Review E, 100, 063108.
[33] Khatri, H., and P. Berloff, 2019: Tilted drifting jets over a zonally sloped topography: Effects of vanishing eddy viscosity. J. Fluid Mech., 876, 939--961.
[34] Ryzhov, E., D. Kondrashov, N. Agarwal, and P. Berloff, 2019: On data-driven augmentation of low-resolution ocean model dynamics. Ocean Modelling, 142, 101464.
[35] Kamenkovich, I., P. Berloff, and I. Rypina, 2019: Anisotropic and inhomogeneous eddy-induced transport in flows with jets. Zonal Jets, B. Galperin and P. Read, eds., Cambridge University Press, Cambridge, 550pp.
[36] Berloff, P., and I. Kamenkovich, 2019: Dynamics of baroclinic multiple zonal jets. Zonal Jets, B. Galperin and P. Read, eds., Cambridge University Press, Cambridge, 550pp.
[37] Khatri, H., and P. Berloff, 2018: Role of eddies in the maintenance of multiple jets embedded in eastward and westward baroclinic shears. Fluids, 3, 91, doi:10.3390/fluids3040091.
[38] Haigh, M., and P. Berloff, 2018: Potential vorticity redistribution by localised transient forcing in the shallow-water model. J. Fluid Mech., 852, 199--225.
[39] Berloff, P., 2018: Dynamically consistent parameterization of mesoscale eddies. Part III: Deterministic approach. Ocean Modelling, 127, 1--15.
[40] Khatri, H., and P. Berloff, 2018: A mechanism for jet drift over topography. J. Fluid Mech., 845, 392--416.
[41] Kondrashov, D., M. Chekroun, and P. Berloff, 2018: Multiscale Stuart-Landau emulators: Application to wind-driven ocean gyres. Fluids, 3, 21. doi:10.3390/fluids3010021.
[42] van Sebille, E., S. Griffies, ..., P. Berloff, ..., 2018: Lagrangian ocean analysis: Fundamentals and practices. Ocean Modelling, 121, 49-75.
[43] Kamenkovich, I., and P. Berloff, 2017: Role of nonlinear eddy forcing in the dynamics of multiple zonal jets. Advances in Nonlinear Geosciences, A. Tsonis, eds., Springer, 707pp.
[44] Shevchenko, I., and P. Berloff, 2017: On the roles of baroclinic modes in eddy-resolving midlatitude ocean dynamics. Ocean Modelling, 111, 55--65.
[45] Chen, C., I. Kamenkovich, and P. Berloff, 2016: Eddy trains and striations in quasigeostrophic simulations and the ocean. J. Phys. Oceanogr., 46, 2807--2825.
[46] Berloff, P., 2016: Dynamically consistent parameterization of mesoscale eddies. Part II: Eddy fluxes and diffusivity from transient impulses. Fluids, 1, 22, doi:10.3390/fluids1030022.
[47] Shevchenko, I., and P. Berloff, 2016: Eddy backscatter and counter-rotating gyre anomalies of midlatitude ocean dynamics. Fluids, 1, 28, doi:10.3390/fluids1030028.
[48] Shevchenko, I., P. Berloff, D. Guerrero-Lopez, and J. Roman, 2016: On low-frequency variability of the midlatitude ocean gyres. J. Fluid Mech., 795, 423--442.
[49] Shevchenko, I., and P. Berloff, 2015: Multi-layer quasi-geostrophic ocean dynamics in eddy-resolving regimes. Ocean Modelling, 94, 1--14.
[50] Kondrashov, D., and P. Berloff, 2015: Stochastic modeling of decadal variability in ocean gyres. Geophys. Res. Lett., 42, 1543--1553.
[51] Kamenkovich, I., I. Rypina, and P. Berloff, 2015: Properties and origins of the anisotropic eddy-induced transport in the North Atlantic. J. Phys. Oceanogr., 45, 778--791.
[52] Chen, C., I. Kamenkovich, and P. Berloff, 2015: On the dynamics of flows induced by topographic ridges. J. Phys. Oceanogr., 45, 927--940.
[53] Berloff, P., 2015: Dynamically consistent parameterization of mesoscale eddies. Part I: Simple model. Ocean Modelling, 87, 1--19.
[54] Berloff, P. and I. Kamenkovich, 2013a: On spectral analysis of mesoscale eddies. Part I: Linear analysis. J. Phys. Oceanogr., 43, 2505--2527.
[55] Berloff, P. and I. Kamenkovich, 2013b: On spectral analysis of mesoscale eddies. Part II: Nonlinear analysis. J. Phys. Oceanogr., 43, 2528--2544.
[56] Rypina, I., I. Kamenkovich, P. Berloff, and L. Pratt, 2012: Eddy-induced particle dispersion in the near-surface North Atlantic. J. Phys. Oceanogr., 42, 2206--2228.
[57] Marshall, D., J. Maddison, and P. Berloff, 2012: A framework for parameterizing eddy potential vorticity fluxes. J. Phys. Oceanogr., 42, 539--557.
[58] Hogg, A., W. Dewar, P. Berloff, and M. Ward, 2011: Kelvin wave hydraulic control induced by interactions between vortices and topography. J. Fluid Mech., 687, 194--208.
[59] Berloff, P., S. Karabasov, T. Farrar, and I. Kamenkovich, 2011: On latency of multiple zonal jets in the oceans. J. Fluid Mech., 686, 534--567.
[60] Dewar, W., P. Berloff, and A. Hogg, 2011: Submesoscale generation by boundaries. J. Mar. Res., 69, 501--522.
[61] Deremble, B., A. Hogg, P. Berloff, and W. Dewar, 2011: On the application of no-slip lateral boundary conditions to coarsely resolved ocean models. Ocean Modelling, 39, 411--415.
[62] Kamenkovich, I., P. Berloff, and J. Pedlosky, 2009b: Anisotropic material transport by eddies and eddy-driven currents in a model of the North Atlantic. J. Phys. Oceanogr., 39, 3162--3175.
[63] Berloff, P., I. Kamenkovich, and J. Pedlosky, 2009a: A model of multiple zonal jets in the oceans: Dynamical and kinematical analysis. J. Phys. Oceanogr., 39, 2711--2734.
[64] Hogg, A., W. Dewar, P. Berloff, S. Kravtsov, and D. Hutchinson, 2009: The effects of mesoscale ocean-atmosphere coupling on the large-scale ocean circulation. J. Climate, 22, 4066--4082.
[65] Berloff, P., I. Kamenkovich, and J. Pedlosky, 2009b: A mechanism of formation of multiple zonal jets in the oceans. J. Fluid Mech., 628, 395--425.
[66] Kamenkovich, I., P. Berloff, and J. Pedlosky, 2009a: Role of eddy forcing in the dynamics of multiple zonal jets in the North Atlantic. J. Phys. Oceanogr., 39, 1361--1379.
[67] Karabasov, S., P. Berloff, and V. Goloviznin, 2009: CABARET in the ocean gyres. Ocean Modelling, 30, 155--168.
[68] Kravtsov, S., W. Dewar, M. Ghil, J. McWilliams, and P. Berloff, 2008: A mechanistic model of mid-latitude decadal climate variability. Physica D, 237, 584--599.
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[71] Kravtsov, S., W. Dewar, P. Berloff, J. McWilliams, and M. Ghil, 2007: A highly nonlinear coupled mode of decadal variability in a midlatitude ocean-atmosphere model. Dyn. Atmos. Ocean., 43, 123--150.
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