Micro-refractive element stabilized resonators, lasers and multiple beam lasing

The invention claimed is: 1. An optical resonator, comprising: opposing mirrors arranged substantially parallel to each other and separated to confine reflections therebetween; a gain medium between the opposing mirrors; a pump to pump the gain medium; and a least one microrefractive element to stabilize the resonator, the microrefractive element being disposed between said opposing mirrors and configured and sized to support a laser beam at a position of the microrefractive element. 2. The resonator of claim 1 , comprising a plurality of microrefractive elements. 3. The resonator of claim 2 , wherein said plurality comprises hundreds to millions. 4. The resonator of claim 2 , wherein said microrefractive element comprises a microsphere or hemisphere. 5. The resonator of claim 4 , wherein the opposing mirrors are separated by a distance of ˜20-200 μm. 6. The resonator of claim 5 , wherein said microsphere has a diameter of ˜10-200 μm. 7. The resonator of claim 4 , wherein said microsphere is upon the surface of one of said opposing mirrors. 8. The resonator of claim 4 , wherein said microsphere is attached to surface of one of said opposing mirrors via optical adhesive. 9. The resonator of claim 8 , wherein said microsphere comprises a plurality of microspheres or hemispheres arranged in a pattern. 10. The resonator of claim 9 , wherein said pattern is a hexagonal pattern. 11. The resonator of claim 4 , wherein said microsphere comprises a solid microsphere or hemisphere. 12. The resonator of claim 11 , wherein said microsphere comprises sapphire, glass, diamond, or an infrared material. 13. The resonator of claim 4 , wherein said microsphere comprises liquid or gases inside a solid shell. 14. The resonator of claim 2 , wherein said microrefractive element comprises a biological cell. 15. The resonator of claim 14 , wherein said biological cell comprises Chlamydomonas Reinhardtii. 16. The resonator of claim 14 , comprising a resonator volume between said opposing mirrors, said resonator volume being divided into two sections by a window, wherein one of the two sections of the resonator volume contains said gain medium and the other contains a biological solution with a plurality of biological cells. 17. The resonator of claim 1 , comprising a resonator volume between said opposing mirrors, said resonator volume being divided into two sections by a window, wherein one of the two sections of the resonator volume contains a first gain medium and the other contains a second gain medium and a plurality of microrefractive elements. 18. The resonator of claim 1 , comprising a resonator volume between said opposing mirrors, said resonator volume containing a plurality of microrefractive elements. 19. The resonator of claim 18 , wherein said plurality of microrefractive elements are suspended in a liquid or gas. 20. The resonator of claim 1 , wherein said gain medium comprises a rare earth doped disk. 21. The resonator of claim 20 , wherein said at least one microrefractive element is upon said disk, and said disk is upon one of said opposing mirrors. 22. The resonator of claim 20 , further comprising a heat sink to cool the resonator. 23. The resonator of claim 1 , comprising a plurality of gain media separated from each other. 24. An imaging system including a resonator of claim 1 , the imaging system further including optics to focus a plurality of laser beams from the resonator onto a sample and optics and an image sensor for sensing an image of the sample. 25. A monitoring and feedback system including a resonator of claim 1 , the monitoring and feedback system further including optics to divert a portion of the energy of a plurality of laser beams from the resonator onto a detector, a feedback controller and an actuator to move one of opposing mirrors. 26. The monitoring and feedback system of claim 25 , wherein said one of said opposing mirrors comprising a plurality of micromirrors. 27. A method for producing laser light, the method comprising: directing pump light onto one or a plurality of microrefractive elements; with mirrors, confining reflections from the one or a plurality of microrefractive elements in a resonator volume; providing gain in the resonator volume; and emitting laser energy from the resonator volume. 28. The method of claim 27 , comprising a plurality of microrefractive elements, wherein said emitting comprises emitting individual laser energy from each of said plurality of microrefractive elements. 29. The method of claim 28 , wherein said emitting comprises emitting a predetermined pattern of individual laser energy based upon a pattern of said plurality of microrefractive elements.