High power CW mid-IR laser

The invention claimed is: 1. A continuous wave (“CW”) laser with a mid-IR output comprising: a resonant cavity; a gain medium being formed into a ring rotatable about an axis defined by an inner circumferential surface, an outer circumferential surface, a first face and a second face, the gain medium with a first non-stationary gain portion between the first and second faces within the resonant cavity to provide first mid-IR gain, and a second non-stationary gain portion spaced radially from the first non-stationary portion and located between the first and second faces within the resonant cavity to provide supplementary mid-IR gain; a first pump source outputting a first pump beam propagating through the first non-stationary gain portion parallel to the axis and sufficient to emit the first CW laser beam so as to provide the first mid-IR gain; a second pump source outputting a second beam propagating through the second non-stationary gain portion parallel to the axis and sufficient to emit a CW laser second laser beam so as to provide the second mid-IR gain; a rotatable mounting structure in thermal contact with the ring, and a motor coupled to the rotatable mounting structure to rotate the ring about the axis; and wherein the first and second non-stationary gain portions of the ring in transit through the resonant cavity receive respective second and first laser beams so as to increase a power of the mid-IR output. 2. The CW laser of claim 1 , wherein the gain medium is selected from polycrystalline transition metal doped II-VI materials (TM:II-VI). 3. The CW laser of claim 1 , wherein the gain medium is characterized as of Cr:ZnSe. 4. The CW laser of claim 1 , wherein the gain medium is characterized as of Cr:ZnS. 5. The CW laser of claim 1 , further comprising at least one optical cavity element for mid-IR output wavelength selection. 6. The CW laser of claim 1 , further comprising at least one optical cavity element for narrowing the spectral line width of the mid-IR output. 7. The CW laser of claim 1 , wherein the gain medium is a composite stacked ring gain element. 8. The CW laser of claim 1 , wherein the first non stationary gain portion and the second non-stationary gain portion each provide gain in the resonant cavity. 9. The CW laser of claim 1 , wherein the first non-stationary gain portion provides gain as a master oscillator and the second non-stationary gain portion provides single pass amplification to output from the master oscillator. 10. The CW laser of claim 1 , wherein the resonant cavity comprises a cavity mirror proximate to the first face of the ring and an output coupler proximate to the first face of the ring. 11. The CW laser of claim 1 , further comprising optical elements for redirecting the optical path from the first gain portion to the second gain portion, the optical elements disposed proximate to the second face of the ring. 12. The CW laser of claim 1 , further comprising optical elements for focusing the first and second pump sources to respective first and second gain portions of the ring. 13. The CW laser of claim 1 , further comprising one or more lens elements for focusing mid-IR light. 14. The CW laser of claim 1 , wherein the first non-stationary gain portion provides gain in a first resonant cavity and the second non-stationary gain portion provides gain in a second resonant cavity. 15. The CW laser of claim 14 , further comprising at least one beam combiner optical element, wherein the first non-stationary gain portion provides a first output, the second non-stationary gain portion provides a second output, and the beam combiner combines the first and second outputs into the mid-IR output.