Divided pulse lasers

The invention claimed is: 1. A pulsed laser that generates high energy pulses by dividing laser pulses and recombining laser pulses within a laser cavity, comprising: an optical cavity including a first mirror, and a second mirror to direct light to travel between the first mirror and the second mirror; a set of optical dividing/combining elements positioned between the first mirror and the second mirror within the optical cavity and having a first side and second side; an optical amplifier positioned within the optical cavity on the second side of the set of optical dividing/combining elements; wherein the optical cavity is configured to: direct a laser pulse of linearly polarized light into the set of optical dividing/combining elements from the first side to divide the laser pulse into a sequence of temporally spaced sub-pulses, wherein each sub-pulse has a lower pulse energy than an input laser pulse; and direct the sequence of sub-pulses into the optical amplifier to produce a sequence of amplified sub-pulses; wherein the first mirror is configured to direct the sequence of amplified sub-pulses back into the set of optical dividing/combining elements from the second side to recombine the sequence of amplified sub-pulses into a single amplified laser pulse having a greater pulse energy than the laser pulse; and wherein the optical cavity is configured to output a portion of the single amplified laser pulse as the output pulse of the pulsed laser. 2. The pulsed laser of claim 1 , wherein each of the set of optical dividing/combining elements is configured to divide an input pulse into two temporally spaced sub-pulses in a first direction from the first side to the second side and combine two input pulses into a single pulse in a second direction from the second side to the first side. 3. The pulsed laser of claim 1 , wherein the pulsed laser is a soliton laser that includes a dispersive delay module for providing anomalous dispersion. 4. The pulsed laser of claim 3 , wherein the dispersive delay module includes a grating pair. 5. The pulsed laser of claim 1 , wherein the second mirror is saturable absorber mirror (SAM). 6. The pulsed laser of claim 5 , wherein the second mirror is semiconductor saturable absorber mirror (SESAM). 7. The pulsed laser of claim 1 , wherein the optical amplifier includes a fiber gain medium. 8. The pulsed laser of claim 7 , wherein the fiber gain medium includes a ytterbium (Yb)-doped fiber. 9. The pulsed laser of claim 7 , wherein the optical cavity includes a Faraday rotator positioned between the first mirror and the fiber gain medium. 10. The pulsed laser of claim 9 , wherein the Faraday rotator and the first mirror together serve as a retro-reflector and are configured to cancel an effect due to a birefringence of the fiber gain medium. 11. The pulsed laser of claim 1 , wherein the optical dividing/combining elements include yttrium vanadate crystals. 12. The pulsed laser of claim 1 , wherein the set of optical dividing/combining elements are arranged as a set of successive dividing stages along the light path, and the input laser pulse is divided in each successive dividing stage. 13. The pulsed laser of claim 1 , wherein the optical amplifier is in a double-pass configuration to pass and amplify the sequence of sub-pulses once in each direction. 14. The pulsed laser of claim 1 , wherein the single amplified laser pulse at the first side of the set of optical dividing/combining elements is polarized substantially orthogonal to the polarization of the input laser. 15. The pulsed laser of claim 1 , wherein the number of pulses in the sequence of sub-pulses is N, and the number of elements in the set of optical dividing/combining elements is M, wherein N=2 M . 16. The pulsed laser of claim 1 , wherein the pulse energy of the single amplified laser pulse is 2 M × of the pulse energy of the input laser pulse. 17. A method for operating a pulsed laser by dividing laser pulses and recombining laser pulses within a laser cavity, comprising: inside a laser cavity, directing a laser pulse of linearly polarized light to divide the laser pulse into a sequence of temporally spaced sub-pulses, wherein each sub-pulse has a lower pulse energy than an input laser pulse; amplifying the sequence of sub-pulses in an optical amplifier in the laser cavity to produce a sequence of amplified sub-pulses; and recombining, inside the laser cavity, the sequence of amplified sub-pulses into a single amplified laser pulse with a greater pulse energy than the input laser pulse; and redirecting a portion of the single amplified laser pulse as the output pulse of the pulsed laser. 18. The method as in claim 17 , wherein the single amplified laser pulse is polarized orthogonally to the input laser pulse. 19. The method as in claim 17 , comprising using a set of optical dividing/combining elements inside the laser cavity to divide the laser pulse into the sequence of temporally spaced sub-pulses. 20. The method as in claim 17 , wherein the set of optical dividing/combining elements include yttrium vanadate crystals. 21. The method as in claim 17 , wherein the set of optical dividing/combining elements are arranged as a set of successive dividing stages along the light path, so that the input laser pulse is divided in each successive dividing stage. 22. The method as in claim 17 , wherein the optical amplifier includes a ytterbium-doped fiber configured in a double-pass configuration, and wherein amplifying the sequence of sub-pulses includes directing the sequence of sub-pulses to pass through the fiber once in each direction, thereby amplifying sequence of sub-pulses twice through the fiber. 23. A method for operating a pulsed laser by dividing laser pulses and recombining laser pulses within a laser cavity, comprising: inside a laser cavity, directing a laser pulse of linearly polarized light to divide the laser pulse into a sequence of temporally spaced sub-pulses, wherein each sub-pulse has a lower pulse energy than an input laser pulse; amplifying the sequence of sub-pulses in an optical amplifier in the laser cavity to produce a sequence of amplified sub-pulses; and recombining, inside the laser cavity, the sequence of amplified sub-pulses into a single amplified laser pulse with a greater pulse energy than the input laser pulse; and redirecting a portion of the single amplified laser pulse as the output pulse of the pulsed laser wherein recombining the sequence of amplified sub-pulses includes directing the sequence of amplified sub-pulses into the same set of optical dividing/combining elements in the opposite direction to the dividing process. 24. The method as in claim 23 , wherein the single amplified laser pulse is polarized orthogonally to the input laser pulse. 25. The method as in claim 23 , wherein the set of optical dividing/combining elements are arranged as a set of successive dividing stages along the light path, so that the input laser pulse is divided in each successive dividing stage. 26. The method as in claim 23 , wherein the optical amplifier includes a ytterbium-doped fiber configured in a double-pass configuration, and wherein amplifying the sequence of sub-pulses includes directing the sequence of sub-pulses to pass through the fiber once in each direction, thereby amplifying sequence of sub-pulses twice through the fiber. 27. A puls