A pairing, in cryptography, is a way to make three-party operations.
Suppose that you have three groups G1, G2 and G3, in which discrete logarithm is hard. Let's note group operation additively (with a '+' sign) in G1 and G2, and multiplicatively in G3. A pairing e is a function which takes one element of G1 and one element of G2, and outputs an element of G3, such that, for all integers a and b, and all group elements X1 and Y1 (from G1) and X2 and Y2 (from G2), you get:
e(X1 + X2, Y1) = e(X1, Y1) e(X2, Y1) (pairing is linear in the first parameter)
e(X1, Y1 + Y2) = e(X1, Y1) e(X1, Y2) (pairing is linear in the second parameter)
e(aX, bY) = e(X, Y)ab (actually a consequence of the bilinearity explained above)
An example of a very weak pairing is the following: let p and q be two prime numbers such that q divides p-1. Let g be a multiplicative generator of a sub-group or order q modulo p (i.e. g is not 1, but gq = 1 mod p). Define G1 and G2 to be the integers modulo q, with addition as group operation. Define G3 to be the subgroup generated by g. Then, define e as: e(X, Y) = gXY mod p. This gives you a non-degenerate pairing ("non-degenerate" means that the pairing can return values other than 1). But it is useless for cryptography because "discrete logarithm" in G1 and G2 is a matter of a simple modular division, i.e. very easy to compute efficiently (because we used integer addition as group law).
A non-weak pairing can be used for identity-based cryptography (where the public key of someone is their email address, not some mathematical object linked to the address through a signed certificate -- the point being, precisely, to avoid a PKI). It can also be used for three-party Diffie-Hellman, or more generally protocols which involve three entities at a time (e.g. protocols for "electronic cash" or some voting systems). See this page for some details and links.
The currently only known cryptographically strong pairings, but still usable in practice, are based on specially crafted elliptic curves. See Ben Lynn's PhD dissertation for a mathematical introduction, and PBC for the implementation. An "easy" variant will make G1 and G2 an elliptic curve over a field GF(p) (for a prime integer p), and G3 will be a multiplicative subgroup of the invertible elements in GF(p2). Be warned that it is somewhat higher-level mathematics than "plain" elliptic curves (you have to know how field extensions work).