Y. A. Omelchenko scite author profile

Global hybrid (electron fluid, kinetic ions) and fully kinetic simulations of the magnetosphere have been used to show surprising interconnection between shocks, turbulence, and magnetic reconnection. In particular, collisionless shocks with their reflected ions that can get upstream before retransmission can generate previously unforeseen phenomena in the post shocked flows: (i) formation of reconnecting current sheets and magnetic islands with sizes up to tens of ion inertial length. (ii) Generation of large scale low frequency electromagnetic waves that are compressed and amplified as they cross the shock. These "wavefronts" maintain their integrity for tens of ion cyclotron times but eventually disrupt and dissipate their energy. (iii) Rippling of the shock front, which can in turn lead to formation of fast collimated jets extending to hundreds of ion inertial lengths downstream of the shock. The jets, which have high dynamical pressure, "stir" the downstream region, creating large scale disturbances such as vortices, sunward flows, and can trigger flux ropes along the magnetopause. This phenomenology closes the loop between shocks, turbulence, and magnetic reconnection in ways previously unrealized. These interconnections appear generic for the collisionless plasmas typical of space and are expected even at planar shocks, although they will also occur at curved shocks as occur at planets or around ejecta. V C 2014 AIP Publishing LLC. [http://dx.

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A new asynchronous methodology for modeling of physical systems: breaking the curse of courant condition

Karimabadi

Driscoll

Omelchenko

et al. 2005

Journal of Computational Physics

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Computer simulation of many important complex physical systems has reached a plateau because most conventional techniques are ill equipped to deal with the multi-scale nature of such systems. The traditional technique to simulate physical systems modeled by partial differential equations consists of breaking the simulation domain into a spatial grid and then advancing the state of the system synchronously at regular discrete time intervals. This socalled time-driven (or time-stepped) simulation (TDS) has inherent inefficiencies such as the time step restriction imposed by a global CFL (Courant-Friedrichs-Levy) condition. There is ongoing research on introducing local time refinement (local versus global CFL) within the time-stepped methodology. Here, we propose an entirely different (asynchronous) simulation methodology which uses the spatial grid but the time advance is based on a discrete event-driven (as opposed to time-driven) approach. This new technique immediately offers several major advantages over TDS. First, it allows each part of the simulation, that is the individual cells in case of fluid simulations and individual particles within a cell in case of particle simulations, to evolve based on their own physically determined time scales. Second, unlike in the TDS where the system is updated faithfully in time based on a pre-selected user specified time step, here the role of time step is replaced by a threshold for local state change. In our technique, individual parts of the global simulation state are updated on a ''need-to-be-done-only'' basis. Individual parts of the simulation domain set their own time scales for change, which may vary in space as well as during the run. In a particle-in-cell (PIC) simulation, DES enables a self-adjusting temporal mesh for each simulation entity down to assigning an individual time step to each particle. In this paper, we illustrate this new technique via the example of a spacecraft charging in a neutral plasma due to injection of a charged beam particle from its surface and compare its performance with the traditional techniques. We find that even in one-dimension, the new DES technology can be more than 300 times faster than the traditional TDS. Aside from sheer performance advantages, the real power of this technique is in its inherent ability to adapt to the spatial inhomogeneity of the problem. This enables building intelligent algorithms where interaction of simulation entities (e.g., cells, particles) follow elementary rules set by the

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Exact charge-conserving scatter–gather algorithm for particle-in-cell simulations on unstructured grids: A geometric perspective

Moon

Teixeira

Omelchenko³

2015

Computer Physics Communications

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Self-adaptive time integration of flux-conservative equations with sources

Omelchenko

Karimabadi

2006

Journal of Computational Physics

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Y. A. Omelchenko

The link between shocks, turbulence, and magnetic reconnection in collisionless plasmas

A new asynchronous methodology for modeling of physical systems: breaking the curse of courant condition

Exact charge-conserving scatter–gather algorithm for particle-in-cell simulations on unstructured grids: A geometric perspective

Self-adaptive time integration of flux-conservative equations with sources

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