Dieses Bild zeigt Magiera

M. Sc.

Jim Magiera

Research assistant
Institute of Applied Analysis and Numerical Simulation
Chair of Applied Mathematics

Contact

+49 711 685-67646

Pfaffenwaldring 57
70569  Stuttgart
Deutschland
Room: 7.330

Consultation

Please arrange appointment by mail.

  1. J. Magiera and C. Rohde, “A Particle-based Multiscale Solver for Compressible Liquid-Vapor  Flow,” erscheint bei Springer Proc. Math. Stat., 2017.
  2. C. Chalons, J. Magiera, C. Rohde, and M. Wiebe, “A Finite-Volume Tracking Scheme for Two-Phase Compressible Flow,” erscheint bei Springer Proc. Math. Stat., 2017.
  3. I. Rybak and J. Magiera, “Decoupled schemes for free flow and porous medium systems,” in Domain Decomposition Methods in Science and Engineering XXII, 2016, vol. 104, pp. 613--621.
  4. J. Magiera, C. Rohde, and I. Rybak, “A hyperbolic-elliptic model problem for coupled surface-subsurface  flow,” Transp. Porous Media, vol. 114, no. 2, pp. 425–455, 2016.
  5. J. Magiera, C. Rohde, and I. Rybak, “A Hyperbolic-Elliptic Model Problem for Coupled Surface-Subsurface Flow,” TRANSPORT IN POROUS MEDIA, vol. 114, no. 2, SI, pp. 425–455, 2016.
  6. I. Rybak, J. Magiera, R. Helmig, and C. Rohde, “Multirate time integration for coupled saturated/unsaturated porous  medium and free flow systems,” Comput. Geosci., vol. 19, pp. 299--309, 2015.
  7. I. Rybak, J. Magiera, R. Helmig, and C. Rohde, “Multirate time integration for coupled saturated/unsaturated porous    medium and free flow systems,” COMPUTATIONAL GEOSCIENCES, vol. 19, no. 2, pp. 299–309, 2015.
  8. I. Rybak and J. Magiera, “A multiple-time-step technique for coupled free flow and porous medium  systems,” J. Comput. Phys., vol. 272, pp. 327--342, 2014.