Method and system for linearizing non-linear optics

1 . A method of nonlinear optical interaction in a nonlinear medium, comprising interacting at least one input beam in a nonlinear medium located at a spectrally dispersed plane. 2 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam. 3 . The method of claim 2 , wherein the input beam is a beam of ultrashort pulses. 4 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, wherein said spectrally dispersing the beam comprises performing a Fourier transformation on the beam, said interacting taking place in the frequency domain. 5 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, wherein said spectrally dispersing the beam comprises performing a first Fourier transformation on the beam, said interacting taking place in the frequency domain, the method further comprising performing a second Fourier transformation after said interacting to yield an output beam in the time domain. 6 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, wherein said spectrally dispersing the beam comprises using multiple dispersive elements. 7 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, wherein said spectrally dispersing the beam comprises using multiple dispersive elements selected in the group consisting of plane gratings, curved gratings, prisms, grisms and a combination thereof. 8 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, wherein said spectrally dispersing the beam comprises using multiple dispersive elements, the dispersive elements having planes of dispersion that are one of: parallel, perpendicular, and at an angle between zero and ninety degrees. 9 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, further comprising tailoring the spectrally dispersed plane by using an optical system. 10 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, further comprising tailoring the spectrally dispersed plane by using an optical system, said tailoring comprising one of: i) adjusting the focal spot size in the spectrally dispersed plane, ii) varying a total expansion in wavelengths spatially across the spectrally dispersed plane, and iii) changing an angle between different incident frequencies. 11 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, further comprising tailoring the spectrally dispersed plane by using an optical system selected in the group consisting of lenses, mirrors or a combination thereof. 12 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, further comprising a spherical cylindrical optic that collimates the dispersed beam in a first plane and an optical system that focuses the different frequencies in a second plane perpendicular to the first plane. 13 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally dispersed pump beam, the input beam being a beam of ultrashort pulses, further comprising focusing dispersed spectral components to a point or a line. 14 . The method of claim 1 , comprising at least partly pumping the spectrally dispersed plane with a spectrally undispersed pump beam. 15 - 22 . (canceled) 23 . The method of claim 1 , comprising placing the spectrally dispersed plane inside a laser cavity. 24 . The method of claim 1 , wherein the nonlinear medium located at the spectrally dispersed plane is a real level pumped lasing material placed inside an oscillator. 25 . (canceled) 26 . The method of claim 1 , wherein an output spectrum after said interacting in the nonlinear medium located at the spectrally dispersed plane is larger than the input spectrum. 27 . (canceled) 28 . A method of ultra-broadband phase conjugation, comprising interacting at least one input beam in a nonlinear medium located at a spectrally dispersed plane. 29 . (canceled) 30 . (canceled) 31 . A system for non linear interaction of a beam of ultrashort pulses, comprising: one of: i) a dispersive element, dispersing an input beam and a collimating optic collimating frequencies of the dispersed beam; and ii) multiple dispersive elements; and a nonlinear medium, located at the spectrally dispersed plane, for interaction with the beam. 32 . The system of claim 31 , further comprising an optical system before the nonlinear medium. 33 . (canceled) 34 . (canceled)