Publications

Scientific Journal Publications

• W. Regulski, J. Szumbarski, Ł. Łaniewski-Wołłk, K. Gumowski, J. Skibiński, M. Wichrowski, T. Wejrzanowski, Pressure drop in flow across ceramic foams-A numerical and experimental study, Chemical Engineering Science, 2015-12-01
• Ł. Łaniewski-Wołłk, J. Rokicki, Adjoint Lattice Boltzmann for topology optimization on multi-GPU architecture, Computers and Mathematics with Applications, 2016-02-01
• M. Dzikowski, L. Łaniewski-Wołłk, J. Rokicki, Single component multiphase lattice boltzmann method for taylor/bretherton bubble train flow simulations, Communications in Computational Physics, 2016-04-01
• M. Dzikowski, L. Jasinski, M. Dabrowski, Depth-averaged Lattice Boltzmann and Finite Element methods for single-phase flows in fractures with obstacles, Computers and Mathematics with Applications, 2018-05-15
• T. Mitchell, C. Leonardi, A. Fakhari, Development of a three-dimensional phase-field lattice Boltzmann method for the study of immiscible fluids at high density ratios, International Journal of Multiphase Flow, 2018-10-01
• J.W.S. McCullough, C.R. Leonardi, B.D. Jones, S.M. Aminossadati, J.R. Williams, Investigation of local and non-local lattice Boltzmann models for transient heat transfer between non-stationary, disparate media, Computers and Mathematics with Applications, 2020-01-01
• G. Gruszczyński, T. Mitchell, C. Leonardi, Ł. Łaniewski-Wołłk, T. Barber, A cascaded phase-field lattice Boltzmann model for the simulation of incompressible, immiscible fluids with high density contrast, Computers and Mathematics with Applications, 2020-02-15
• J.W.S. McCullough, S.M. Aminossadati, C.R. Leonardi, Transport of particles suspended within a temperature-dependent viscosity fluid using coupled LBM–DEM, International Journal of Heat and Mass Transfer, 2020-03-01
• T. Mitchell, C. Leonardi, Development of closure relations for the motion of Taylor bubbles in vertical and inclined annular pipes using high-fidelity numerical modeling, Physics of Fluids, 2020-06-01
• M. Rutkowski, W. Gryglas, J. Szumbarski, C. Leonardi, Łaniewski-Wołłk, Open-loop optimal control of a flapping wing using an adjoint Lattice Boltzmann method, Computers and Mathematics with Applications, 2020-06-15
• T. Mitchell, C. Leonardi, On the rise characteristics of Taylor bubbles in annular piping, International Journal of Multiphase Flow, 2020-09-01
• T.R. Mitchell, M. Majidi, M.H. Rahimian, C.R. Leonardi, Computational modeling of three-dimensional thermocapillary flow of recalcitrant bubbles using a coupled lattice Boltzmann-finite difference method, Physics of Fluids, 2021-03-01
• D. Wang, Z. You, R.L. Johnson, L. Wu, P. Bedrikovetsky, S.M. Aminossadati, C.R. Leonardi, Numerical investigation of the effects of proppant embedment on fracture permeability and well production in Queensland coal seam gas reservoirs, International Journal of Coal Geology, 2021-06-01
• B.M. Hill, C.R. Leonardi, Lattice Boltzmann simulation of transient blood flow in arterial geometries using a regularised, viscoplastic and shear-thinning fluid, International Journal for Numerical Methods in Biomedical Engineering, 2021-08-01
• J.W.S. McCullough, Ł. Łaniewski-Wołłk, S.M. Aminossadati, C.R. Leonardi, A 3D LBM-DEM study of sheared particle suspensions under the influence of temperature-dependent viscosity, Powder Technology, 2021-09-01
• M. Matyka, M. Dzikowski, Memory-efficient Lattice Boltzmann Method for low Reynolds number flows, Computer Physics Communications, 2021-10-01
• N.J. Di Vaira, L. Łaniewski-Wołłk, R.L. Johnson, S.M. Aminossadati, C.R. Leonardi, Influence of particle polydispersity on bulk migration and size segregation in channel flows, Journal of Fluid Mechanics, 2022-05-25
• G. Gruszczyński, Ł. Łaniewski-Wołłk, A comparative study of 3D cumulant and central moments lattice Boltzmann schemes with interpolated boundary conditions for the simulation of thermal flows in high Prandtl number regime, International Journal of Heat and Mass Transfer, 2022-11-15
• T.R. Mitchell, A. Roslin, Ł. Łaniewski-Wołłk, I. Onederra, C.R. Leonardi, Quantifying the Permeability Enhancement from Blast-Induced Microfractures in Porphyry Rocks Using a Cumulant Lattice Boltzmann Method, Transport in Porous Media, 2023-02-01

Conferences

• Dzikowski, M., 2013, "Single Component Multiphase Lattice Boltzmann method for tribological flow computations", ICCMES 2013, Oxford
• Dzikowski, M., Rokicki, J., Antoszewski, B., 2013, "Lattice boltzmann method for multiphase flow in face seals", X Workshop "Modelling of Multiphase Flows in Thermo-Chemical Systems", Gdańsk
• Dzikowski, M., Rokicki, 2013, "Lattice Boltzmann method for multiphase tribological flow computations , ECCOMAS PARTICLES 2013, Stuttgart
• Dzikowski, M., Rokicki, J., 2013. "Metoda Gazu sieciowego Boltzmanna w symulacjach przepływów trybologicznych ze zmianą fazy", Terotechnologia, Kielce

• Dzikowski, M., Rokicki, J. 2014, "Lattice Boltzmann method as a fine scale solver in multiscale method modeling surface texture , ECCOMAS CFD 2014
• Dzikowski, M., Rokicki, J. 2014, "Lattice boltzman method for multiphase tribological flows", KKMP 2014

• Dzikowski, M., Rokicki, J. 2015, "Accuracy of Lattice Boltzmann Method in application to multiphase tribological flows", 3rd PCM & 21st CMM 2015
• Dzikowski, M., Rokicki, J. 2015, "Reliability of the interaction potential based Lattice Boltzmann method for multiphase tribological flows", PARTICLES 2015, Barcelona

• G. Gruszczyński, 2016, "Adjoint Lattice Boltzmann Method for Optimal Control" European Postgraduate Fluid Dynamic Conference, Warsaw.

• Dąbrowski M., Dzikowski M., Jasiński Ł., and Olkiewicz P. , 2017, "Numerical modeling of multiphase flow in rough and propped fractures", EGU2017, Wiedeń
• Dzikowski M. and Dąbrowski M., 2017, "Viscosity and surface tension effects during multiphase flow in propped fractures", EGU2017, Wiedeń

• Gruszczyński G., Łaniewski-Wołłk Ł., 2018 "Modelling of immiscible multiphase flows using phase-field, Cascaded Lattice Boltzmann Method", 16th Multiphase Flow Conference and Short Course, Helmholtz Zentrum Dresden-Rossendorf, Dresden.

• Gruszczyński G., Łaniewski-Wołłk Ł., 2019, "Numerical modelling of Super Hydrophobic Surfaces Using Lattice Boltzmann method (Poster)" XIII Multiphase Workshop and Summer School, The Szewalski Institute of Fluid-Flow Machinery Polish Academy of Sciences (IMP PAN), Wieżyca.

• G.Gruszczyński, Ł. Łaniewski-Wołłk, 2020 "Application of thermal Cascaded Lattice Boltzmann Method to 3D simulations in a high Prandtl number regime (Poster)", The Fourth Spring School on Lattice Boltzmann Methods, 2020, Berlin
• Dzikowski M. and Gruszczyński G., "Templated CUDA Lattice Boltzmann Method: generic CFD solver for single and multi-phase problems.", Supercomputing Frontiers Europe 2020, 2020, Warsaw

• Gruszczyński G., Dzikowski M. and Łaniewski-Wołłk Ł., 2021 "On recovering the second-order convergence of the lattice Boltzmann method with reaction-type source terms", 17th International Conference for Mesoscopic Methods in Engineering and Science (ICMMES 2021), Tunis

PhD Thesis

Warsaw University of Technology

• M. Dzikowski, Wykorzystanie metody gazu sieciowego Boltzmanna do symulacji przepływów dwufazowych (promotor: J. Rokicki)
• Ł. Łaniewski-Wołłk, Topology Optimization and Optimal Control using Adjoint Lattice Boltzmann Method (promotor: J. Rokicki)
• W. Regulski, Investigation of hydrodynamic properties of structures with open porosity using the Lattice Boltzmann Method (promotor: J. Szumbarski)

The University of Queensland

• J. McCullough Numerical investigation of conjugate heat transfer and temperature-dependent viscosity in non-Brownian suspensions with application to hydraulic fracturing, (supervisor: C. Leonardi)
• T. R. Mitchell, Development of a multiphase lattice Boltzmann model for high-density and viscosity ratio flows in unconventional gas wells, 2019 (supervisor: C. Leonardi)

MSc and BSc Works

Warsaw University of Technology

• T. Gajek, Symulacja komputerowa przepływu przez górne drogi oddechowe metodą Lattice Boltzmann (promotor: J. Szumbarski)
• G. Gruszczyński, Optimal Control using the Adjoint Lattice Boltzmann Method (promotor: J. Szumbarski)
• P. Obrępalski, Simulation of car aerodynamics using Lattice Boltzmann method (promotor: Ł. Łaniewski-Wołłk)
• D. Sashko, Simulation of turbulent flows with cummulant Lattice-Boltzman method (promotor: Ł. Łaniewski-Wołłk)
• R. Lenartowicz, Influence of uncertainty of initial conditions in a flapping wing simulation (promotor: Ł. Łaniewski-Wołłk)

The University of Queensland

• D. Lightbody, Computational Modelling of Arterial Plaque Rupture using Coupled Lattice Boltzmann and Discrete Element Methods (supervisor: C. Leonardi)
• W. Martin, Computational Modelling of Particle Straining in Porous Media (supervisor: C. Leonardi)
• R. Dendle, Computational Modelling of Proppant Embedment \& Fracture Permeability in Queensland Coal Seams (supervisor: C. Leonardi)
• L. O'Loughlin, Direct Numerical Simulation of CO2 Sequestration at the Pore Scale (supervisor: C. Leonardi)
• B. Hill Computational Modelling of Pulsatile Blood Flow (supervisor: C. Leonardi)

Projects and Grants

• ShaleSeq: Multidisciplinary project for carbon capture and storage analysis for Pomeranian shales

• MapMoPS: Pre-Exascale project for particle simulations at the University of Queensland and POWSEY supercomputing center.

• IDUB against COVID-19 "Modelling of epidemic spreading with Lattice Boltzmann Method"

• IDUB POB III "Wysokowydajny model numeryczny wspierający analizę danych tomograficznych.

Computing Power Grants

PL-GRID infrastructure (PL)

TCLB was actively developed and extended on the infrastructure of Cyfronet, in the grants: clb, clb2, clb3, clb2016, clb2017, clb2018, clb2019, clb2020, clb2021.

ICM UW infrastructure (PL)

TCLB was actively developed and extended on the infrastructure of Interdisciplinary Centre for Mathematical and Computational Modelling, University of Warsaw, in the grants: GR80-12, GR83-20.

PAWSEY infrastructure (AU)

TCLB was developed and tuned for the Cray architecture as part of computing power grants awarded to the team of Christopher Leonardi (UQ).

Pawsey Centre for Extreme Readiness (AU)

TCLB was selected for development for extreme-scale computing in the project Massively parallel models of particle suspensions.

National Computational Infrastructure (AU)

TCLB was heavily used on the infrastructure at National Computational Infrastructure (NCI), in the grants: aa83, cz84.