Optical coating permitting cavity self-locking

What is claimed is: 1 . A single-carrier optical spring, comprising: a first dielectric mirror having a first dielectric coating comprising a first plurality of layers; a second dielectric mirror having a second dielectric coating comprising a second plurality of layers, wherein the second dielectric mirror is positioned opposite the first dielectric mirror such that the second dielectric coating and first dielectric coating are facing and form an optical cavity between the first dielectric mirror and the second dielectric mirror, and such that a laser beam incident upon the first or second dielectric coating will resonate in the optical cavity formed by the dielectric mirrors, wherein the first layer of the first plurality of layers and the first layer of the second plurality of layers is sized to be an odd multiple of half a wavelength of the incident laser beam. 2 . The single carrier optical spring of claim 1 , wherein the optical cavity is further formed by a third dielectric mirror or an optical lens. 3 . The single-carrier optical spring of claim 1 , wherein the sizes of the first layer of the first plurality of layers and the second plurality of layers are different. 4 . The single carrier optical spring of claim 1 , wherein the first dielectric mirror comprises a receiving surface opposite the first dielectric coating, wherein the first dielectric mirror is configured to receive the laser beam at the receiving surface and to transmit the laser beam from the first dielectric coating, such that the laser beam is incident upon the second dielectric mirror. 5 . The single carrier optical spring of claim 1 , wherein the first mirror is configured to be a mechanical oscillator. 6 . The single carrier optical spring of claim 5 , wherein the first mirror has a mass large enough to remain effectively stationary when subjected to radiation pressure from the incident laser beam. 7 . The single carrier optical spring of claim 1 , wherein the second mirror is configured to be a mechanical oscillator. 8 . The single carrier optical spring of claim 7 , wherein the second mirror has a mass small enough to move in response to radiation pressure exhibited by the incident laser beam. 9 . The single carrier optical spring of claim 5 , wherein the first dielectric mirror is suspended as a single or multi-stage pendulum. 10 . The single carrier optical spring of claim 7 , wherein the second dielectric mirror is suspended as a single or multi-stage pendulum. 11 . The single carrier optical spring of claim 1 , further comprising a laser configured to generate the incident laser beam. 12 . A method of providing cavity self-locking, comprising the steps of: providing a first dielectric mirror having a first dielectric coating comprising a first plurality of layers and a second dielectric mirror having a second dielectric coating comprising a second plurality of layers, wherein the second dielectric mirror and the first dielectric mirror are positioned such that the second dielectric coating and first dielectric coating form an optical cavity and the first layer of the first plurality of layers and the second plurality of layers is sized to be an odd multiple of half a wavelength of the incident laser beam; and targeting a laser beam incident upon the first or second dielectric coating to form a resonating wave between the dielectric mirrors, 13 . The method of claim 12 , wherein the sizes of the first layer of the first plurality of layers and the second plurality of layers are different. 14 . The method of claim 12 , wherein the first dielectric mirror comprises a receiving surface opposite the first dielectric coating, wherein the first dielectric mirror is configured to receive the laser beam at the receiving surface and to transmit the laser beam from the first dielectric coating, such that the laser beam is incident upon the second dielectric mirror. 15 . The method of claim 12 , wherein the first mirror is configured to be a mechanical oscillator. 16 . The method of claim 15 , wherein the first mirror has a mass large enough to remain stationary when subjected to radiation pressure from the incident laser beam. 17 . The method of claim 12 , wherein the second mirror is configured to be a mechanical oscillator. 18 . The method of claim 17 , wherein the second mirror has a mass small enough to move in response to radiation pressure exhibited by the incident laser beam. 19 . The method of claim 18 , wherein the first mirror is suspended as a single or multi-stage pendulum. 20 . The method of claim 17 , wherein the second mirror is suspended as a single or multi-stage pendulum.