Methods and apparatus of entangled photon generation using four-wave mixing

The invention claimed is: 1. An apparatus for generating entangled photons by four-wave mixing, comprising a resonator and an output waveguide for the resonator, wherein: the resonator is an optical disk microresonator or an optical ring microresonator; the resonator has an operating frequency range; the resonator comprises a silicon nitride waveguide clad with a cladding material, the silicon nitride waveguide having a radius dimension r, a thickness dimension h, and a disk diameter dimension or ring width dimension w; an angular wavenumber m represents a number of wavelengths of pump radiation that fit around the resonator when the resonator is pumped by a pump beam of light at a pump frequency, such that each value of m corresponds to a mode having a respective mode frequency; the respective modes are spaced apart in frequency by a Free Spectral Range FSR that varies with frequency, according to a dispersion curve, in a manner that depends on r, h, and w; the dimensions r, h, and w are selected to place a zero-dispersion frequency, where the dispersion curve is at a minimum, within the operating frequency range; the dimensions r, h, and w are further selected to make the dispersion curve steeper on a low-wavenumber side of the zero-dispersion frequency and less steep on a high-wavenumber side of the zero-dispersion frequency; and the apparatus further comprises a broadband optical filter coupled to the output waveguide and configured to separate a first and a second spectral region from a spectral region that intervenes between said first and second spectral regions, and to pass entangled photons in the first and second spectral regions forward for further disposition. 2. The apparatus of claim 1 , wherein the cladding material is silicon dioxide. 3. The apparatus of claim 2 , wherein the resonator is an optical ring microresonator, r is approximately 20 μm, w is approximately 1.1 μm, and h is approximately 750 nm. 4. The apparatus of claim 3 , wherein the zero-dispersion frequency is in the range 1.2-2.0 μm and m at the zero-dispersion frequency is in the range 100-200. 5. The apparatus of claim 4 , wherein m at the zero-dispersion frequency is approximately 137. 6. The apparatus of claim 1 , wherein the zero-dispersion frequency is in the range 1.2-2.0 μm and m at the zero-dispersion frequency is in the range 100-200.