Mid-IR Kerr lens mode locked laser with normal incidence mounting of polycrystalline TM:II-VI materials and method for controlling parameters of polycrystalline TM:II-VI Kerr lens mode locked laser

The invention claimed is: 1. A Kerr Lens Mode Locked (“KLM”) laser comprising: a resonant cavity; and a gain medium selected from polycrystalline transition metal doped II-VI materials (“TM:II-VI), the gain medium being cut at a normal angle of incidence and mounted in the resonant cavity so as to induce Kerr-lens mode locking sufficient for the resonant cavity to emit a train of ultrashort pulses of a laser beam at a fundamental wavelength, wherein ultrashort pulses of the emitted laser beam at the fundamental wavelength, ranging from 1.8 μm to 8 μm, each have a pulse duration equal to at least 30 femtosecond (“fs”) and an average output power of at most 20 watts (“W”), the gain medium being configured with a plurality of microscopic single-crystal grains which are non-uniformly dimensioned and have, differently oriented crystallographic axes. 2. The KLM laser of claim 1 , wherein the gain medium generates second, third and fourth harmonic wavelengths of the fundamental wavelength. 3. The KLM laser of claim 1 , wherein the resonant cavity is planar. 4. The KLM laser of claim 1 , wherein the gain medium includes TM doped binary and ternary materials. 5. The KLM laser of claim 4 , wherein the materials include Cr2+:ZnSe, Cr2+:ZnS, Cr2+:CdSe, Cr2+:CdS, Cr2+:ZnTe, Cr2+:CdMnTe, Cr2+:CdZnTe, Cr2+:ZnSSe, Fe2+:ZnSe, Fe2+:ZnS, Fe2+:CdSe, Fe2+:CdS, Fe2+:ZnTe, Fe2+:CdMnTe, Fe2+:CdZnTe, Fe2+:ZnSSe. 6. The KLM laser of claim 1 further comprising a linearly polarized fiber laser pump source selected from an erbium or thulium doped single mode fiber and operative to emit a pump beam which is coupled into the gain medium at a pump wavelength different from the fundamental wavelength, wherein the laser and pump beams remain circular while propagating through the gain medium. 7. The KLM laser of claim 6 , wherein the gain medium is configured to uniformly release heat in response to the coupled pump beam which generates various uniform, axially symmetric thermal-optical effects inside the pumped gain medium. 8. The KLM laser of claim 1 , wherein the optical intensity inside the gain medium is increased by a factor of n if compared with a conventional Brewster mounting scheme. 9. The KLM laser of claim 1 , wherein the gain medium is configured to substantially compensate for astigmatism of the resonant cavity. 10. The KLM laser of claim 6 , wherein the resonant cavity includes at least two adjacent upstream and downstream dielectrically coated folded mirrors spaced apart along a path of the pump beam and each configured with a high reflectivity at the fundamental wavelength and high transmission at the pump wavelength, the gain medium being located between and spaced from the folded mirrors, the downstream folded mirror being configured to at least partially transmit the high harmonic wavelength. 11. The KLM laser of claim 10 , wherein the resonant cavity further includes a partially transmitting at the fundamental wavelength output coupler, and at least one plane dichroic mirror upstream from the output coupler and configured with the high reflectivity at the fundamental wavelength, and at least one intermediary plate with high transmission at the fundamental and high harmonic wavelength. 12. The KLM laser of claim 10 , wherein the resonant cavity further includes a dispersion compensation element configured as a plane parallel plate or prism and operative to limit a dispersion, which is mounted at a Brewster angle. 13. The KLM laser of claim 10 , wherein the resonant cavity further includes a Brewster mounted birefringent tuner. 14. The KLM laser of claim 10 further comprising a translation stage displacing the gain medium within the resonant cavity along a waist of the laser beam to controllably redistribute the average power of the laser beam among a primary output of the emitted laser beam at the fundamental wavelength and secondary outputs at respective second, third and fourth harmonic wavelengths.