In the original calculation done by Casimir, he considered the space between a pair of conducting metal plates at distance apart. In this case, the standing waves are particularly easy to calculate, because the transverse component of the electric field and the normal component of the magnetic field must vanish on the surface of a conductor. Assuming the plates lie parallel to the -plane, the standing waves are \psi_n(x,y,z;t)=e^{-i\omega_nt} e^{ik_xx+ik_yy} \sin(k_n z) \,, where stands for the electric component of the electromagnetic field, and, for brevity, the polarization and the magnetic components are ignored here. Here, and are the
wavenumbers in directions parallel to the plates, and k_n=\frac{n\pi}{a} is the wavenumber perpendicular to the plates. Here, is an integer, resulting from the requirement that vanish on the metal plates. The frequency of this wave is \omega_n=c \sqrt{{k_x}^2 + {k_y}^2 + \frac{n^2\pi^2}{a^2}} \,, where is the
speed of light. The vacuum energy is then the sum over all possible excitation modes. Since the area of the plates is large, we may sum by integrating over two of the dimensions in -space. The assumption of
periodic boundary conditions yields, \langle E \rangle=\frac{\hbar}{2} \cdot 2 \int \frac{A \,dk_x \,dk_y}{(2\pi)^2} \sum_{n=1}^\infty \omega_n \,, where is the area of the metal plates, and a factor of 2 is introduced for the two possible polarizations of the wave. This expression is clearly infinite, and to proceed with the calculation, it is convenient to introduce a
regulator (discussed in greater detail below). The regulator will serve to make the expression finite, and in the end will be removed. The
zeta-regulated version of the energy per unit-area of the plate is \frac{\langle E(s) \rangle}{A}=\hbar \int \frac{dk_x \,dk_y}{(2\pi)^2} \sum_{n=1}^\infty \omega_n \left| \omega_n \right|^{-s} \,. In the end, the limit is to be taken. Here is just a
complex number, not to be confused with the shape discussed previously. This integral sum is finite for
real and larger than 3. The sum has a
pole at , but may be
analytically continued to , where the expression is finite. The above expression simplifies to: \frac{\langle E(s) \rangle}{A}= \frac{\hbar c^{1-s}}{4\pi^2} \sum_n \int_0^\infty 2\pi q \,dq \left | q^2 + \frac{\pi^2 n^2}{a^2} \right|^\frac{1-s}{2} \,, where
polar coordinates were introduced to turn the
double integral into a single integral. The in front is the Jacobian, and the comes from the angular integration. The integral converges if , resulting in \frac{\langle E(s) \rangle}{A}= -\frac {\hbar c^{1-s} \pi^{2-s}}{2a^{3-s}} \frac{1}{3-s} \sum_n \left| n \right| ^{3-s}= -\frac {\hbar c^{1-s} \pi^{2-s}}{2a^{3-s}(3-s)}\sum_n \frac{1}{\left| n\right| ^{s-3}} \,. The sum diverges at in the neighborhood of zero, but if the damping of large-frequency excitations corresponding to analytic continuation of the
Riemann zeta function to is assumed to make sense physically in some way, then one has \frac{\langle E \rangle}{A}= \lim_{s\to 0} \frac{\langle E(s) \rangle}{A}= -\frac {\hbar c \pi^2}{6a^3} \zeta (-3) \,. But and so one obtains \frac{\langle E \rangle}{A}= -\frac {\hbar c \pi^2}{720 a^3}\,. The analytic continuation has evidently lost an additive positive infinity, somehow exactly accounting for the zero-point energy (not included above) outside the slot between the plates, but which changes upon plate movement within a closed system. The Casimir force per unit area for idealized, perfectly conducting plates with vacuum between them is \frac{F_\mathrm{c}}{A}=-\frac{d}{da} \frac{\langle E \rangle}{A} = -\frac {\hbar c \pi^2} {240 a^4} where • is the
reduced Planck constant, • is the
speed of light, • is the
distance between the two plates The force is negative, indicating that the force is attractive: by moving the two plates closer together, the energy is lowered. The presence of shows that the Casimir force per unit area is very small, and that furthermore, the force is inherently of quantum-mechanical origin. By
integrating the equation above it is possible to calculate the energy required to separate to infinity the two plates as: \begin{align} U_E(a) &= \int F(a) \,da = \int - \hbar c \pi^2 \frac {A} {240 a^4} \,da \\[4pt] &= \hbar c \pi^2 \frac {A} {720 a^3} \end{align} where • is the
reduced Planck constant, • is the
speed of light, • is the
area of one of the plates, • is the
distance between the two plates In Casimir's original derivation, a moveable conductive plate is positioned at a short distance from one of two widely separated plates (distance apart). The zero-point energy on
both sides of the plate is considered. Instead of the above
ad hoc analytic continuation assumption, non-convergent sums and integrals are computed using
Euler–Maclaurin summation with a regularizing function (e.g., exponential regularization) not so anomalous as in the above.
More recent theory Casimir's analysis of idealized metal plates was generalized to arbitrary dielectric and realistic metal plates by
Evgeny Lifshitz and his students. Using this approach, complications of the bounding surfaces, such as the modifications to the Casimir force due to finite conductivity, can be calculated numerically using the tabulated complex dielectric functions of the bounding materials. Lifshitz's theory for two metal plates reduces to Casimir's idealized force law for large separations much greater than the
skin depth of the metal, and conversely reduces to the force law of the
London dispersion force (with a coefficient called a
Hamaker constant) for small , with a more complicated dependence on for intermediate separations determined by the
dispersion of the materials. Lifshitz's result was subsequently generalized to arbitrary multilayer planar geometries as well as to anisotropic and magnetic materials, but for several decades the calculation of Casimir forces for non-planar geometries remained limited to a few idealized cases admitting analytical solutions. However, in the 2010s a number of authors developed and demonstrated a variety of numerical techniques, in many cases adapted from classical
computational electromagnetics, that are capable of accurately calculating Casimir forces for arbitrary geometries and materials, from simple finite-size effects of finite plates to more complicated phenomena arising for patterned surfaces or objects of various shapes. == Measurement ==