The Poiseuille's law (or the Hagen-Poiseuille law also named after Gotthilf Heinrich Ludwig Hagen (1797-1884) for his experiments in 1839) is the physical law concerning the voluminal laminar stationary flow Φ_V of incompressible uniform viscous liquid (so called Newtonian fluid) through a cylindrical tube with the constant circular cross-section, experimentally derived in 1838, formulated and published in 1840 and 1846 by Jean Louis Marie Poiseuille (1797-1869), and defined by:

<math> \Phi_{V} = {dV\over dt} = v_{s}\pi r^{2} = {\pi r^{4}\over 8 \eta} \left( - { d p^{\star} \over dz}\right) = {\pi r^{4}\over 8 \eta} { \Delta p^{\star} \over \ell} \; , <math>

where V is a volume of the liquid, poured in the time unit t, v_s median fluid velocity along the axial cylindrical coordinate z, r internal radius of the tube, Δp^* the preasure drop at the two ends, η dynamic fluid viscosity and l characteristic length along z, a linear dimension in a cross-section (in non-cylindrical tube). The law can be derived from the Darcy-Weisbach equation, developed in the field of hydraulics and which is otherwise valid for all types of flow, and also expressed in the form:

<math> \Lambda = {64\over {\it Re}} \; , \quad\quad Re = {2\rho v_{s} r\over \eta} \; , <math>

where Re is the Reynolds number and ρ fluid density. In this form the law approximates the friction factor, the energy (head) loss factor, friction loss factor or Darcy (friction) factor Λ in the laminar flow at very low velocities in cylindrical tube. The theoretical derivation of slightly different Poiseuille's original form of the law was made independently by Wiedman in 1856 and Neumann and E. Hagenbach in 1858 (1859, 1860). Hagenbach was the first who called this law the Poiseuille's law.

The law is also very important specially in hemorheology and hemodynamics, both fields of physiology.

The Poiseuilles' law was later in 1891 extended to turbulent flow by L. R. Wilberforce, based on Hagenbach's work.

Curiosity

The law itself shows how an interesting field this is, because the Darcy-Weisbach equation should be properly named in full as the Chézy-Weisbach-Darcy-Poiseuille-Hagen-Reynolds-Fanning-Prandtl-Blasius-von Kármán-Nikuradse-Colebrook-White-Rouse-Moody equation or CWDPHRFPBKNCWRM equation in 'short'.

Also note in the formula how strongly the flow depends on the radius. If all else is held constant, a doubling of the radius of the channel results in a sixteen-fold increase in the flow.

Relation to electrical circuit

Electricity was originally understood to be a kind of fluid. This hydraulic analogy is still of some use in teaching.

Poiseuille's law corresponds to the Ohm's law for electrical circuits, where pressure drop Δp^* is somehow replaced by voltage V and voluminal flow rate Φ_V by current I. According to this a term 8η l/πr⁴ is an adequate substitution for the electrical resistance R.

de:Gesetz von Hagen-Poiseuille es:Ley de Poiseuille nl:Wet van Hagen-Poiseuille sl:Poiseuillov zakon