Lava flow on an inclined plane (particles coloured according to their temperature).

<p>Lava flow on an inclined plane (particles coloured according to their temperature).</p

Internal energy versus temperature (assuming <i>e</i>_<i>0</i> = 0 and <i>T</i>_<i>0</i> = 0) in the case of phase transition.

<p>Internal energy versus temperature (assuming <i>e</i>_<i>0</i> = 0 and <i>T</i>_<i>0</i> = 0) in the case of phase transition.</p

Types of interactions occurring between elemental particles.

<p>Types of interactions occurring between elemental particles.</p

Plinko-chip for cell separation (a); evolution of the center of mass for flexible and rigid cells (b).

<p>Plinko-chip for cell separation (a); evolution of the center of mass for flexible and rigid cells (b).</p

Mixing SPH and DEM forces to account for sub-scale solids.

<p>Mixing SPH and DEM forces to account for sub-scale solids.</p

Neutrally buoyant, buoyant and heavy cubic particles in Poiseuille flow.

<p>Neutrally buoyant, buoyant and heavy cubic particles in Poiseuille flow.</p

Fluid dynamics, contact forces and solid mechanics in solid-liquid flows and some modelling techniques available for each case.

<p>Fluid dynamics, contact forces and solid mechanics in solid-liquid flows and some modelling techniques available for each case.</p

Coarse-grain modelling of solids and its molecular origin.

<p>Coarse-grain modelling of solids and its molecular origin.</p

Swelling and erosion of a protein-based soil deposit (particles coloured according to their water content).

<p>Swelling and erosion of a protein-based soil deposit (particles coloured according to their water content).</p

Structure of a typical particle-based algorithm with the internal forces routine highlighted.

<p>Structure of a typical particle-based algorithm with the internal forces routine highlighted.</p