Homepage of Michael Bonitz

Stellen / Positions | Publications

Review papers

Accelerating Nonequilibrium Green functions simulations: the G1-G2 scheme and beyond, Michael Bonitz, Jan-Philip Joost, Christopher Makait, Erik Schroedter, Tim Kalsberger, and Karsten Balzer (2024)
Physics and applications of dusty plasmas: The perspectives 2023, J. Beckers et al. (2023, Feature article)
Electronic Density Response of Warm Dense Matter, T. Dornheim et al. (2023, open access, Editors' pick)
Ab initio simulation of warm dense matter, M. Bonitz, T. Dornheim, Zh.A. Moldabekov, S. Zhang, P. Hamann, A. Filinov, K. Ramakrishna, and J. Vorberger (2020, open access)
Quantum hydrodynamics for plasmas-quo vadis?, M. Bonitz, Zh. Moldabekov, and T. Ramazanov (2019, open access)
Ultrafast Dynamics of Strongly Correlated Fermions -- Nonequilibrium Green Functions and Selfenergy Approximations, N. Schluenzen, S. Hermanns, M. Scharnke, and M. Bonitz (2019, open access)
Towards an integrated modeling of the plasma-solid interface, M. Bonitz, A. Filinov, J.-W. Abraham, K. Balzer, H. Kählert, E. Pehlke, F.X. Bronold, M. Pamperin, M. Becker, D. Loffhagen, and H. Fehske (2019)
The Uniform Electron Gas at Warm Dense Matter Conditions, T. Dornheim, S. Groth, and M. Bonitz, (2018)
Theory of strongly correlated plasmas: phase transitions, transport, quantum, and magnetic field effects, T. Ott, H. Thomsen, J.W. Abraham, T. Dornheim, and M. Bonitz, (2018)
Theoretical foundations of quantum hydrodynamics for plasmas, Zh. Moldabekov, M. Bonitz, and T. Ramazanov, (2018)
Nonequilibrium Green functions approach to strongly correlated fermions in lattice systems, N. Schlünzen, and M. Bonitz, (2016)
Controlling strongly correlated dust clusters with lasers, H. Thomsen, P. Ludwig, M. Bonitz, J. Schablinski, D. Block, A. Schella, and A. Melzer, (2014)
Quantum Breathing Mode of Trapped Particles: from nanoplasmas to ultracold gases, J.W. Abraham and M. Bonitz, (2014)
Time-dependent multiconfiguration methods for the numerical simulation of photoionization processes of many-electron atoms, D. Hochstuhl, C. Hinz, and M. Bonitz (2014)
Quantum Hydrodynamics, S.A. Khan and M. Bonitz (2014)
Kinetic Theory for Quantum Plasmas, M. Bonitz (2012)
Complex plasmas - a laboratory for strong correlations, M. Bonitz et al. (2010)
Classical and quantum Coulomb crystals, M. Bonitz et al. (2008)
Structure formation in correlated Coulomb systems, M. Bonitz et al. (2006)
Quantendynamik korrelierter Coulombsysteme (in German), M. Bonitz (2002)

Scientific interests

• Dense strongly correlated plasmas in astrophysics and laboratory systems
• Plasma-surface interaction
• Quantum kinetic theory, Nonequilibrium Green's functions
• First principle computer simulations
• Excitation dynamics of strongly correlated systems (electrons in solids, atoms in optical lattices etc.)
• Dusty plasmas
• Electron-hole plasmas in bulk semiconductors, quantum wells, quantum wires and quantum dots
• Quantum confined electrons: Wigner crystallization, transport properties
• Linear and nonlinear plasma oscillations and instabilities in plasmas and solids
• Femtosecond relaxation in laser pulse excited semiconductors
• Interaction of charged particles with strong EM fields, in particular lasers, nonlinear phenomena, harmonics generation
• Bound states (atoms, molecules, excitons) in dense plasmas and semiconductors
• Atoms and molecules in strong laser, VUV and x-ray fields
• Selforganization and structure formation in systems far from equilibrium

Theoretical concepts and numerical methods

• Quantum statistical theory, quantum kinetic equations
• Quantum kinetic equations for the Wigner distribution
• Numerical solution of hydrodynamic and transport equations
• Keldysh-Kadanoff-Baym equations for the two-time Green's functions: theory and solution
• Computer simulations: Monte Carlo and molecular dynamics
• Low-temperature plasma simulations: particle in cell and hydrodynamic simulations
• Development of new first-principle simulation methods for quantum systems:
• Path integral Monte Carlo simulations, in particular configuration PIMC and permutation blocking PIMC
• Quantum Molecular Dynamics based on the Wigner-Liouville equation
• Combination of kinetic theory and (other) simulation methods

Stark korrelierte Coulombsysteme

• Vielteilcheneffekte
• Kollektive Quanteneffekte
• Femtosekundenprozesse

Zum Forschungsschwerpunkt "Plasma Theory".

Zum Forschungsschwerpunkt "Plasma Theory"

Strongly correlated quantum systems: Nonequilibrium Green functions approach

Recent applications include: finite Hubbard systems in 1 and 2 dimensions, honeycomb lattices, graphene nanoribbons
Video demonstrations:

• Ion stopping in correlated honeycomb clusters
• Expansion of a 2D fermion cluster following a confinement quench
• Relxaxation of a 1D charge density wave state
• Carrier multiplication in a small graphene cluster following short pulse laser excitation

Zum Forschungsschwerpunkt "Quantum kinetic Theory".

Zum Forschungsschwerpunkt "Quanten Coulombsysteme".

Zum Forschungsschwerpunkt "Trapped Bose condensates".

Zum Forschungsschwerpunkt "Electron-hole bilayers".

Zum Forschungsschwerpunkt "First principle Computersimulationen".

Zum Forschungsschwerpunkt "First principle Computersimulationen".

Research results and scientific interests

• Publications
• Books
• Talks
• In the News
• Research projects

Publication data

Aktuelle Forschung

- Warme dichte Materie, Quantenplasmen
- Quanten-Materialien: Graphen, TMDCs
- Stark korrelierte klassische Plasmen
- Nichtgleichgewichts-Greenfunktionen
- Plasma-Oberflächen-Wechselwirkung
- Photoionisation von Atomen in starken Laserfeldern
- Exzitonen in Bilayern, Bosekondensation
- Astrophysikalische Plasmen in kompakten Sternen

Research Results in Pictures

19 Electrons trapped in a spherical electric field. They form shells like atoms in the Mendeleyev table (notice the symmetry), and they may "freeze", i.e. crystallize like in this figure. The pictures are the result of rigorous quantum Monte Carlo calculations. Read in Physical Review Focus (engl.), Wissenschaft Online (ger.), and Sciences et Avenir (fr.) about our work on Wigner crystallization.

Choosing suitable semiconductor properties, the holes (red) form a crystal, while the electrons (yellow) stay in a gas-like state (a quantum Fermi gas). See story "The Hole Crystal" by Kim Krieger in Physical Review Focus.

Feynman's path integral representation of a trapped 2D quantum system with 3 electrons. The concepts and implementation details of the Path Integral Monte Carlo (PIMC) method are explained in our book "Introduction to Computational Methods in Many-Body Physics".

Coulomb ball of N=160 dust grain with 3 shells and a single particle in the trap center. Obtained from first principle MD simulations.

Klein ist anders, die Ideen der Quantentheorie: Ein allgemeinverständliches Poster anlässlich des 150. Geburtstags von Max Planck. Die Geburtstagsrede zum Nachlesen.

Electrons in a laser pulse excited semi- conductor produce such nice picture. The picture is the result of the numerical solution of quantum kinetic equations (Keldysh-Kadanoff-Baym equations). To learn more about the physical processes in a laser excited semiconductor click here.

Two trapped charged bosons for different densities and temperatures;
PIMC simulation by Jens Böning

Configurational change of 10 e-h pairs in coupled quantum dots upon density reduction; Hartree-Fock calculations by Karsten Balzer