Fiber laser assembly and method of generating light

1 . A fiber laser assembly comprising: a light source for emitting signal light having a non-zero spectral width; a length of passive multimode optical fiber between first and second ends thereof, optically coupled at the first end thereof to the light source for receiving the signal light and propagating the signal light in a zero-order optical mode and a higher-order optical mode in the passive multimode optical fiber towards the second end thereof, wherein upon such propagation, one of the zero-order or higher-order optical modes is delayed with respect to the other optical mode so as to at least partially reduce coherence therebetween at the second end of the passive multimode optical fiber due to the non-zero spectral width of the signal light; and a length of active multimode optical fiber between first and second ends thereof, optically coupled at the first end thereof to the second end of the passive multimode optical fiber, for receiving and amplifying the zero-order optical mode as the zero-order optical mode propagates towards the second end of the active multimode optical fiber. 2 . The fiber laser assembly of claim 1 , wherein the spectral width of the light source is between 1 nm and 5 nm, and wherein the length of the passive multimode optical fiber is at least 5 mm. 3 . The fiber laser assembly of claim 1 , wherein the spectral width of the light source is between 0.1 nm and 1 nm, and the length of the passive multimode optical fiber is at least 50 mm. 4 . The fiber laser assembly of claim 1 , wherein the length of the passive multimode optical fiber is such that coherence is completely lost between the zero-order and higher-order optical modes. 5 . The fiber laser assembly of claim 1 , wherein the passive and active multimode optical fibers include outer diameters differing from each other by less than 10%. 6 . The fiber laser assembly of claim 5 , wherein the passive and active multimode optical fibers include core numerical apertures differing from each other by less than 10%. 7 . The fiber laser assembly of claim 5 , wherein the light source comprises a fiber oscillator. 8 . The fiber laser assembly of claim 7 , wherein the fiber oscillator comprises a length of double clad multimode oscillator fiber between first and second ends thereof; the passive multimode optical fiber comprises a double clad passive multimode optical fiber optically coupled to the second end of the double clad multimode oscillator fiber; the active multimode optical fiber comprises a double clad active multimode optical fiber optically coupled to the double clad passive multimode optical fiber; and the fiber laser assembly further comprises a pump source optically coupled to the first end of the double clad multimode oscillator fiber for pumping the double clad multimode oscillator fiber and the double clad active multimode optical fiber. 9 . The fiber laser assembly of claim 8 , wherein the length of the passive double clad multimode optical fiber is at least 1 mm. 10 . The fiber laser assembly of claim 8 , wherein a core diameter of the passive double clad multimode optical fiber is less than a core diameter of the double clad active multimode optical fiber. 11 . The fiber laser assembly of claim 9 , wherein in operation, the zero-order optical mode propagating in the active multimode optical fiber includes a mode diameter of at least 15 micrometers. 12 . The fiber laser assembly of claim 8 , rated for an average output optical power of at least 100 W. 13 . A fiber laser assembly comprising: a light source for emitting signal light having a finite coherence length; a passive multimode optical fiber having opposed first and second ends and optically coupled at the first end thereof to the light source for receiving the signal light and propagating the signal light in a zero-order optical mode and a higher-order optical mode in the passive multimode optical fiber towards the second end thereof, wherein upon such propagation, one of the zero-order or higher-order optical mode is delayed by a first distance with respect to the other optical mode due to intermodal dispersion in the passive multimode optical fiber to reduce coherence due to a spectral width of the signal light, and wherein the first distance is at least 1% of the coherence length of the signal light; and an active multimode optical fiber having opposed first and second ends and optically coupled at the first end thereof to the second end of the passive multimode optical fiber, for amplifying the zero-order optical mode as the zero-order optical mode propagates towards the second end of the active multimode optical fiber. 14 . The fiber laser assembly of claim 13 , wherein the passive and active multimode optical fibers include outer diameters matching to within 10% of each other. 15 . The fiber laser assembly of claim 14 , wherein the passive and active multimode optical fibers include zero-order mode diameters matching to within 10% of each other. 16 . The fiber laser assembly of claim 15 , wherein the light source comprises an active singlemode optical fiber. 17 . A method comprising: providing passive and active multimode optical fibers each having opposed first and second ends; optically coupling the second end of the passive multimode optical fiber to the first end of the active multimode optical fiber; coupling signal light having a non-zero spectral width to the first end of the passive multimode optical fiber, thereby causing a zero-order optical mode of the signal light to co-propagate with a higher-order optical mode of the signal light from the first to the second end of the passive multimode optical fiber, wherein upon such propagation, one of the zero-order or higher-order optical mode is delayed with respect to the other, so as to at least partially reduce coherence therebetween due to the non-zero spectral width of the signal light, before the zero-order and higher-order optical modes are coupled to the first end of the active multimode optical fiber; and optically pumping the active multimode optical fiber, so as to amplify the zero-order optical mode as the zero-order optical mode propagates towards the second end of the active multimode optical fiber. 18 . The method of claim 17 , wherein the optically coupling is performed by disposing the passive and active multimode optical fibers coaxially, so that the coupling of the signal light substantially does not transfer optical power of the zero-order optical mode to a higher-order optical mode in the active multimode optical fiber. 19 . The method of claim 18 , wherein the passive and active multimode optical fibers include outer diameters matching to within 10% of each other, and the optically coupling comprises fusion splicing the second end of the passive multimode optical fiber to the first end of the active multimode optical fiber. 20 . The method of claim 17 , wherein providing the passive and active multimode optical fibers includes providing double clad passive and active multimode optical fibers.