Publications

1. D. Caparello, T. Tenna.  A Coupled IMEX Domain Decomposition Method for High-Order Time Integration of the ES-BGK Model of the Boltzmann Equation, submitted (2025).

arXiv:2512.03586 [math.NA]

2.  T. Tenna. Relaxation Schemes for Flows in Networks: Application to Shallow Water and Blood Flow Equations, submitted (2025).

arXiv:2512.02989 [math.NA] [hal-04981107]

3. T. Tenna. Projective integration schemes for nonlinear degenerate parabolic systems, submitted (2025).

arXiv:2503.05017 [math.NA] [hal-04981107]

1. G. Puppo, T. Rey, T. Tenna. Formal derivation of an isentropic two-phase flow model from the multi-species Boltzmann equation, accepted for publication in Physical Review E. 

DOI: https://doi.org/10.1103/qph7-wc2m

Preprint version: arXiv:2506.13480 [math.AP] [hal-05115202]

2. M. Menci, R. Natalini, T. Tenna. Numerical study on a multi-dimensional pressureless Euler-type model with non-local interactions and chemotaxis for collective cell migration, SIAM Multiscale Modeling and Simulation, Vol 24 Iss. 1 (2026).
   DOI: https://epubs.siam.org/doi/abs/10.1137/25M1751189
   Preprint version: arXiv:2508.03439 [math.NA] 

3. M. Menci, T. Paul, S. Rossi, T. Tenna. Numerical modeling of flocking dynamics with topological interactions, Communications in Computational Physics Vol. 39 No. 1 (2026).
   DOI: https://doi.org/10.4208/cicp.OA-2025-0078 

Preprint version: arXiv:2503.12980  [math.AP] [hal-04992313]

4. T. Rey, T. Tenna. The Boltzmann equation for a multi-species inelastic mixture, J Stat Phys 192, 151 (2025).
   DOI: https://doi.org/10.1007/s10955-025-03532-8 

Preprint version: arXiv:2410.17027  [math.AP] [hal-04748574]