Neglecting surface tension and viscosity, the equation was first derived by W. H. Besant in his 1859 book with the problem statement stated as An infinite mass of homogeneous incompressible fluid acted upon by no forces is at rest, and a spherical portion of the fluid is suddenly annihilated; it is required to find the instantaneous alteration of pressure at any point of the mass, and the time in which the cavity will be filled up, the pressure at an infinite distance being supposed to remain constant (in fact, Besant attributes the problem to Cambridge Senate-House problems of 1847).^[5] Besant predicted the time required to fill an empty cavity of initial radius ${\displaystyle R_{0}}$  to be

${\displaystyle {\begin{aligned}t&=R_{0}{\sqrt {\frac {6\rho }{P_{\infty }}}}\int _{0}^{1}{\frac {z^{4}\,dz}{\sqrt {1-z^{6}}}}\\&=R_{0}{\sqrt {\frac {\pi \rho }{6P_{\infty }}}}{\frac {\Gamma (5/6)}{\Gamma (4/3)}}\\&\approx 0.91468R_{0}{\sqrt {\frac {\rho }{P_{\infty }}}}\end{aligned}}}$ 

Lord Rayleigh found a simpler derivation of the same result, based on conservation of energy. The kinetic energy of the inrushing fluid is ${\displaystyle 2\pi \rho U^{2}R^{3}}$  where ${\displaystyle R}$  is the time-dependent radius of the void, and ${\displaystyle U}$  the radial velocity of the fluid there. The work done by the fluid pressing in at infinity is ${\displaystyle 4\pi P_{\infty }(R_{0}^{3}-R^{3})/3}$ , and equating these two energies gives a relation between ${\displaystyle R}$  and ${\displaystyle U}$ . Then, noting that ${\displaystyle U=\partial R/\partial t}$ , separation of variables gives Besant's result. Rayleigh went further than Besant, in evaluating the integral (Euler's beta function) in terms of gamma functions. Rayleigh adapted this approach to the case of a cavity filled with an ideal gas (a bubble) by including a term for the work done compressing the gas.

For the case of the perfectly empty void, Rayleigh determined that the pressure ${\displaystyle P}$  in the fluid at a radius ${\displaystyle r}$  is given by:

${\displaystyle {\frac {P}{P_{\infty }}}-1={\frac {R}{3r}}\left({\frac {R_{0}^{3}}{R^{3}}}-4\right)-{\frac {R^{4}}{3r^{4}}}\left({\frac {R_{0}^{3}}{R^{3}}}-1\right)}$ 

When the void is at least one quarter of its initial volume, then the pressure decreases monotonically from ${\displaystyle P_{\infty }}$  at infinity to zero at ${\displaystyle R}$ . As the void shrinks further a pressure maximum, greater than ${\displaystyle P_{\infty }}$  appears at

${\displaystyle r^{3}={\frac {4(R_{0}^{3}-R^{3})R^{3}}{R_{0}^{3}-4R^{3}}}}$ 

very rapidly growing and converging on the void.

The equation was first applied to traveling cavitation bubbles by Milton S. Plesset in 1949 by including effects of surface tension.^[6]

The Rayleigh–Plesset equation can be derived entirely from first principles using the bubble radius as the dynamic parameter.^[3] Consider a spherical bubble with time-dependent radius ${\displaystyle R(t)}$ , where ${\displaystyle t}$  is time. Assume that the bubble contains a homogeneously distributed vapor/gas with a uniform temperature ${\displaystyle T_{B}(t)}$  and pressure ${\displaystyle P_{B}(t)}$ . Outside the bubble is an infinite domain of liquid with constant density ${\displaystyle \rho _{L}}$  and dynamic viscosity ${\displaystyle \mu _{L}}$ . Let the temperature and pressure far from the bubble be ${\displaystyle T_{\infty }}$  and ${\displaystyle P_{\infty }(t)}$ . The temperature ${\displaystyle T_{\infty }}$  is assumed to be constant. At a radial distance ${\displaystyle r}$  from the center of the bubble, the varying liquid properties are pressure ${\displaystyle P(r,t)}$ , temperature ${\displaystyle T(r,t)}$ , and radially outward velocity ${\displaystyle u(r,t)}$ . Note that these liquid properties are only defined outside the bubble, for ${\displaystyle r\geq R(t)}$ .

Mass conservation edit

By conservation of mass, the inverse-square law requires that the radially outward velocity ${\displaystyle u(r,t)}$  must be inversely proportional to the square of the distance from the origin (the center of the bubble).^[6] Therefore, letting ${\displaystyle F(t)}$  be some function of time,

${\displaystyle u(r,t)={\frac {F(t)}{r^{2}}}}$ 

In the case of zero mass transport across the bubble surface, the velocity at the interface must be

${\displaystyle u(R,t)={\frac {dR}{dt}}={\frac {F(t)}{R^{2}}}}$ 

which gives that

${\displaystyle F(t)=R^{2}dR/dt}$ 

In the case where mass transport occurs, the rate of mass increase inside the bubble is given by

${\displaystyle {\frac {dm_{V}}{dt}}=\rho _{V}{\frac {dV}{dt}}=\rho _{V}{\frac {d(4\pi R^{3}/3)}{dt}}=4\pi \rho _{V}R^{2}{\frac {dR}{dt}}}$ 

with ${\displaystyle V}$  being the volume of the bubble. If ${\displaystyle u_{L}}$  is the velocity of the liquid relative to the bubble at ${\displaystyle r=R}$ , then the mass entering the bubble is given by

${\displaystyle {\frac {dm_{L}}{dt}}=\rho _{L}Au_{L}=\rho _{L}(4\pi R^{2})u_{L}}$ 

with ${\displaystyle A}$  being the surface area of the bubble. Now by conservation of mass ${\displaystyle dm_{v}/dt=dm_{L}/dt}$ , therefore ${\displaystyle u_{L}=(\rho _{V}/\rho _{L})dR/dt}$ . Hence

${\displaystyle u(R,t)={\frac {dR}{dt}}-u_{L}={\frac {dR}{dt}}-{\frac {\rho _{V}}{\rho _{L}}}{\frac {dR}{dt}}=\left(1-{\frac {\rho _{V}}{\rho _{L}}}\right){\frac {dR}{dt}}}$ 

Therefore

${\displaystyle F(t)=\left(1-{\frac {\rho _{V}}{\rho _{L}}}\right)R^{2}{\frac {dR}{dt}}}$ 

In many cases, the liquid density is much greater than the vapor density, ${\displaystyle \rho _{L}\gg \rho _{V}}$ , so that ${\displaystyle F(t)}$  can be approximated by the original zero mass transfer form ${\displaystyle F(t)=R^{2}dR/dt}$ , so that^[6]

${\displaystyle u(r,t)={\frac {F(t)}{r^{2}}}={\frac {R^{2}}{r^{2}}}{\frac {dR}{dt}}}$ 

Momentum conservation edit

Assuming that the liquid is a Newtonian fluid, the incompressible Navier–Stokes equation in spherical coordinates for motion in the radial direction gives

${\displaystyle \rho _{L}\left({\frac {\partial u}{\partial t}}+u{\frac {\partial u}{\partial r}}\right)=-{\frac {\partial P}{\partial r}}+\mu _{L}\left[{\frac {1}{r^{2}}}{\frac {\partial }{\partial r}}\left(r^{2}{\frac {\partial u}{\partial r}}\right)-{\frac {2u}{r^{2}}}\right]}$ 

Substituting kinematic viscosity ${\displaystyle \nu _{L}=\mu _{L}/\rho _{L}}$  and rearranging gives

${\displaystyle -{\frac {1}{\rho _{L}}}{\frac {\partial P}{\partial r}}={\frac {\partial u}{\partial t}}+u{\frac {\partial u}{\partial r}}-\nu _{L}\left[{\frac {1}{r^{2}}}{\frac {\partial }{\partial r}}\left(r^{2}{\frac {\partial u}{\partial r}}\right)-{\frac {2u}{r^{2}}}\right]}$ 

whereby substituting ${\displaystyle u(r,t)}$  from mass conservation yields

${\displaystyle -{\frac {1}{\rho _{L}}}{\frac {\partial P}{\partial r}}={\frac {2R}{r^{2}}}\left({\frac {dR}{dt}}\right)^{2}+{\frac {R^{2}}{r^{2}}}{\frac {d^{2}R}{dt^{2}}}-{\frac {2R^{4}}{r^{5}}}\left({\frac {dR}{dt}}\right)^{2}={\frac {1}{r^{2}}}\left(2R\left({\frac {dR}{dt}}\right)^{2}+R^{2}{\frac {d^{2}R}{dt^{2}}}\right)-{\frac {2R^{4}}{r^{5}}}\left({\frac {dR}{dt}}\right)^{2}}$ 

Note that the viscous terms cancel during substitution.^[6] Separating variables and integrating from the bubble boundary ${\displaystyle r=R}$  to ${\displaystyle r\rightarrow \infty }$  gives

${\displaystyle -{\frac {1}{\rho _{L}}}\int _{P(R)}^{P(\infty )}dP=\int _{R}^{\infty }\left[{\frac {1}{r^{2}}}\left(2R\left({\frac {dR}{dt}}\right)^{2}+R^{2}{\frac {d^{2}R}{dt^{2}}}\right)-{\frac {2R^{4}}{r^{5}}}\left({\frac {dR}{dt}}\right)^{2}\right]dr}$ 

${\displaystyle {{\frac {P(R)-P_{\infty }}{\rho _{L}}}=\left[-{\frac {1}{r}}\left(2R\left({\frac {dR}{dt}}\right)^{2}+R^{2}{\frac {d^{2}R}{dt^{2}}}\right)+{\frac {R^{4}}{2r^{4}}}\left({\frac {dR}{dt}}\right)^{2}\right]_{R}^{\infty }=R{\frac {d^{2}R}{dt^{2}}}+{\frac {3}{2}}\left({\frac {dR}{dt}}\right)^{2}}}$ 

Boundary conditions edit

Let ${\displaystyle \sigma _{rr}}$  be the normal stress in the liquid that points radially outward from the center of the bubble. In spherical coordinates, for a fluid with constant density and constant viscosity,

${\displaystyle \sigma _{rr}=-P+2\mu _{L}{\frac {\partial u}{\partial r}}}$ 

Therefore at some small portion of the bubble surface, the net force per unit area acting on the lamina is

${\displaystyle {\begin{aligned}\sigma _{rr}(R)+P_{B}-{\frac {2\sigma }{R}}&=-P(R)+\left.2\mu _{L}{\frac {\partial u}{\partial r}}\right|_{r=R}+P_{B}-{\frac {2\sigma }{R}}\\&=-P(R)+2\mu _{L}{\frac {\partial }{\partial r}}\left({\frac {R^{2}}{r^{2}}}{\frac {dR}{dt}}\right)_{r=R}+P_{B}-{\frac {2\sigma }{R}}\\&=-P(R)-{\frac {4\mu _{L}}{R}}{\frac {dR}{dt}}+P_{B}-{\frac {2\sigma }{R}}\\\end{aligned}}}$ 

where ${\displaystyle \sigma }$  is the surface tension.^[6] If there is no mass transfer across the boundary, then this force per unit area must be zero, therefore

${\displaystyle P(R)=P_{B}-{\frac {4\mu _{L}}{R}}{\frac {dR}{dt}}-{\frac {2\sigma }{R}}}$ 

and so the result from momentum conservation becomes

${\displaystyle {\frac {P(R)-P_{\infty }}{\rho _{L}}}={\frac {P_{B}-P_{\infty }}{\rho _{L}}}-{\frac {4\mu _{L}}{\rho _{L}R}}{\frac {dR}{dt}}-{\frac {2\sigma }{\rho _{L}R}}=R{\frac {d^{2}R}{dt^{2}}}+{\frac {3}{2}}\left({\frac {dR}{dt}}\right)^{2}}$ 

whereby rearranging and letting ${\displaystyle \nu _{L}=\mu _{L}/\rho _{L}}$  gives the Rayleigh–Plesset equation^[6]

${\displaystyle {\frac {P_{B}(t)-P_{\infty }(t)}{\rho _{L}}}=R{\frac {d^{2}R}{dt^{2}}}+{\frac {3}{2}}\left({\frac {dR}{dt}}\right)^{2}+{\frac {4\nu _{L}}{R}}{\frac {dR}{dt}}+{\frac {2\sigma }{\rho _{L}R}}}$ 

Using dot notation to represent derivatives with respect to time, the Rayleigh–Plesset equation can be more succinctly written as

${\displaystyle {\frac {P_{B}(t)-P_{\infty }(t)}{\rho _{L}}}=R{\ddot {R}}+{\frac {3}{2}}({\dot {R}})^{2}+{\frac {4\nu _{L}{\dot {R}}}{R}}+{\frac {2\sigma }{\rho _{L}R}}}$ 

More recently, analytical closed-form solutions were found for the Rayleigh–Plesset equation for both an empty and gas-filled bubble ^[7] and were generalized to the N-dimensional case.^[8] The case when the surface tension is present due to the effects of capillarity were also studied.^[8][9]

Also, for the special case where surface tension and viscosity are neglected, high-order analytical approximations are also known.^[10]

In the static case, the Rayleigh–Plesset equation simplifies, yielding the Young–Laplace equation:

${\displaystyle P_{B}-P_{\infty }={\frac {2\sigma }{R}}}$ 

When only infinitesimal periodic variations in the bubble radius and pressure are considered, the RP equation also yields the expression of the natural frequency of the bubble oscillation.