Pulsed laser with intracavity frequency conversion aided by extra-cavity frequency conversion

What is claimed is: 1. A pulsed laser system, comprising: a pulsed laser configured to generate fundamental laser pulses in a laser resonator, the laser resonator including an output coupler for outputting a portion of each fundamental laser pulse; an extra-cavity nonlinear crystal, external to the laser resonator, for frequency-doubling at least a fraction of each fundamental laser pulse received from the output coupler, so as to generate second-harmonic laser pulses; and an intracavity nonlinear crystal, located in the laser resonator, for generation of third-harmonic laser pulses from sum-frequency mixing of (a) the fundamental laser pulses as propagating in the laser resonator and (b) the second-harmonic laser pulses as received from the extra-cavity nonlinear crystal. 2. The pulsed laser system of claim 1 , wherein the laser resonator includes a Q-switch. 3. The pulsed laser system of claim 2 , wherein the output coupler is an output coupling mirror partially transmissive to the fundamental laser pulses. 4. The pulsed laser system of claim 2 , wherein the output coupler has an output coupling efficiency in the range between 20% and 50%. 5. The pulsed laser system of claim 1 , wherein the pulsed laser is a cavity-dumped laser, and the laser resonator includes an adjustable modulator configured to control loss of the laser resonator, perform cavity dumping, and function as the output coupler. 6. The pulsed laser system of claim 1 , wherein the pulsed laser is a solid-state laser configured to generate the fundamental laser pulses with an average power of at least 1000 watts in the laser resonator. 7. The pulsed laser system of claim 1 , further comprising: a first dichroic mirror for coupling the second-harmonic laser pulses into the laser resonator such that the second-harmonic laser pulses co-propagate collinearly with the fundamental laser pulses through the intracavity nonlinear crystal; and a second dichroic mirror for coupling the third-harmonic laser pulses out of the laser resonator. 8. The pulsed laser system of claim 7 , wherein the second dichroic mirror is configured to couple the third-harmonic laser pulses and the second-harmonic laser pulses out of the laser resonator, and the pulsed laser system further comprises a third dichroic mirror external to the laser cavity and configured to separate the third-harmonic laser pulses from the second-harmonic laser pulses. 9. The pulsed laser system of claim 1 , wherein the laser resonator is a linear resonator and includes a laser gain medium for light amplification to generate the fundamental laser pulses, and wherein the intracavity nonlinear crystal being between the laser gain medium and the output coupler, the pulsed laser system further comprising one or more beam-steering elements not intersecting the fundamental laser pulses in the laser resonator and each configured to steer either (i) the fundamental laser pulses to the extra-cavity nonlinear crystal or (ii) the second-harmonic laser pulses toward the laser resonator, so as to direct the second-harmonic laser pulses through the intracavity nonlinear crystal at a non-zero acute angle with respect to propagation direction of the fundamental laser pulses in direction toward the output coupler. 10. The pulsed laser system of claim 1 , further comprising, externally to the laser resonator, at least one beam-shaping element for optimizing transverse mode of the second-harmonic laser pulses in the intracavity nonlinear crystal independently of beam shape of the fundamental laser pulses. 11. The pulsed laser system of claim 1 , wherein a combined path length L, of (i) the fundamental laser pulses from the output coupler to the extra-cavity nonlinear crystal and (ii) the second-harmonic laser pulses from the extra-cavity nonlinear crystal to the intracavity nonlinear crystal, is less than 0.1cτ, wherein τ is an average pulse width of each fundamental laser pulse, c is the speed of light, and τ is at least 1 nanosecond. 12. A pulsed laser system with intracavity frequency conversion aided by extra-cavity frequency conversion, comprising: a pulsed laser configured to generate fundamental laser pulses in a laser resonator, the laser resonator including an output coupler for outputting a portion of each fundamental laser pulse; one or more extra-cavity nonlinear crystals, external to the laser resonator, for frequency converting at least a portion of each fundamental laser pulse received from the output coupler, so as to generate first frequency-converted laser pulses; and an intracavity nonlinear crystal, located in the laser resonator, for generating second frequency-converted laser pulses from mixing of (a) the fundamental laser pulses as propagating in the laser resonator and (b) the first frequency-converted laser pulses as received from the extra-cavity nonlinear crystals. 13. The pulsed laser system of claim 12 , wherein: the one or more extra-cavity nonlinear crystals are a plurality M of doubling crystals, optically arranged in series, to generate the first frequency-converted laser pulses as an N th harmonic of the fundamental laser pulses, N=2 M ; and the intracavity nonlinear crystal is configured to perform sum-frequency generation so as to generate the second frequency-converted laser pulses as an (N+1) th harmonic of the fundamental laser pulses. 14. The pulsed laser system of claim 12 , further comprising a second laser for generating a second laser radiation, the one or more extra-cavity nonlinear crystals being configured to generate the first frequency-converted laser pulses at least in part via sum-frequency-mixing or difference-frequency-mixing with the second laser radiation. 15. The pulsed laser system of claim 14 , wherein the one or more extra-cavity nonlinear crystals are implemented as an optical parametric amplifier or optical parametric oscillator configured to generate the first frequency-converted laser pulses from mixing of the fundamental laser pulses with the second laser radiation. 16. The pulsed laser system of claim 14 , wherein the one or more extra-cavity nonlinear crystals are implemented as a sum-frequency-generator configured to generate the first frequency-converted laser pulses from sum-frequency-mixing of the fundamental laser pulses with the second laser radiation. 17. A method for frequency conversion of pulsed laser radiation, comprising the steps of: generating fundamental laser pulses in a laser resonator of a pulsed laser; coupling a portion of each fundamental laser pulse out of the laser resonator via an output coupler of the laser resonator; in one or more extra-cavity nonlinear crystals outside the laser resonator, converting the frequency of at least a fraction of each fundamental laser pulse, received from the output coupler, to generate first frequency-converted laser pulses; directing the first frequency-converted laser pulses into the laser resonator; in an intracavity nonlinear crystal inside the laser resonator, generating second frequency-converted laser pulses by mixing (a) the first frequency-converted laser pulses received from the one or more extra-cavity nonlinear crystals with (b) the fundamental laser pulses propagating in the laser resonator. 18. The method of claim 17 , comprising: in the converting step, a step of frequency doubling at least a fraction of each fundamental laser pulse to generate second-harmonic laser pulses; and in the generating second frequency-converted laser pulses step, a step of generating third-harmonic laser pulses from sum-frequency mixing of th