High output maximum efficiency resonator

What is claimed is: 1. A laser system consisting essentially of the following components: a laser head comprising a diode-side-pumped ND:YAG slab laser configured as a zig-zag slab gain medium, the laser head configured to produce a laser beam along an optical path; a Q-switch aligned along the optical path and configured to pulse a laser beam produced by the laser head; a ¼ wave-plate aligned along the optical path and configured to polarize a pulsed laser beam formed by the Q-switch; a graded reflectivity mirror aligned along the optical path and configured to partially reflect and partially transmit a polarized, pulsed laser beam produced by the ¼ wave-plate, and to form a reflected laser beam along a reflected optical path; a cylindrical lens aligned along the reflected optical path and configured to focus a reflected laser beam; and a high reflectivity mirror aligned along the reflected optical path and configured to reflect a focused reflected laser beam produced by the cylindrical lens. 2. The laser system of claim 1 , wherein the laser system is configured to hold average internal fluences to below 3.0 J/cm 2 . 3. The laser system of claim 1 , wherein the laser system is configured to hold average internal fluences to below 2.0 J/cm 2 . 4. The laser system of claim 1 , further consisting essentially of an enclosure, wherein the components are housed within the enclosure. 5. A laser system of claim 4 , configured to direct a transmitted, polarized, pulsed laser beam exiting the enclosure, directly toward a surface of the Earth. 6. The laser system of claim 4 , wherein the enclosure has a single aperture, and the single aperture is configured to transmit a polarized, pulsed laser beam from the graded reflectivity mirror along the optical path to be output from the enclosure. 7. In combination, the laser system of claim 4 and a spacecraft, wherein the laser system is mounted in or on the spacecraft and is configured to direct a transmitted, polarized, pulsed laser beam exiting the enclosure, directly toward a surface of the Earth. 8. The combination of claim 7 , wherein the spacecraft is configured to direct a transmitted, polarized, pulsed laser beam exiting the enclosure, directly toward biomass on the surface of the Earth. 9. The combination of claim 7 , wherein the spacecraft is configured to direct a transmitted, polarized, pulsed laser beam exiting the enclosure, directly toward biomass on the surface of the Earth, and to turn off the laser system when the spacecraft is in orbit above water-covered surfaces of the Earth. 10. A method of forming 7 mJ TEM 00 laser pulses, comprising forming laser pulses with the laser system of claim 1 , without further amplification. 11. A method of forming 15 mJ TEM 00 laser pulses, comprising forming laser pulses with the laser system of claim 1 , without further amplification. 12. A method of analyzing global ecosystems, comprising: generating and directing pulsed laser beams from a laser system according to claim 1 , from a spacecraft, toward a surface of the Earth; and analyzing reflected laser light returning to the spacecraft after reflecting off of the surface of the Earth. 13. The method of claim 12 further comprising calculating the density of biomass at the surface of the Earth based on the reflected laser light. 14. The method of claim 12 , wherein the generating and directing comprises producing 15 mJ TEM 00 laser pulses with the laser system and pulsing such laser pulses toward the Earth for at least two years.