Cladding light stripper and method of manufacturing

What is claimed is: 1. A cladding light stripper comprising: a double-clad optical fiber having a core for guiding signal light, an inner cladding surrounding the core, and an outer cladding surrounding the inner cladding, the double-clad optical fiber including a stripped portion, and the outer cladding being removed, thereby forming an exposed section of an outer surface of the inner cladding, the exposed section including a plurality of transversal notches, disposed along the double-clad optical fiber, to enable light to escape the inner cladding upon impinging on the plurality of transversal notches, each of the plurality of transversal notches having a depth of only a partial distance to the core, each of the plurality of transversal notches having a pitch from 1 notch/cm to 1000 notches/cm, and the plurality of transversal notches including at least 10 notches. 2. The cladding light stripper of claim 1 , wherein the core includes a dopant for amplifying the signal light when pumped by pump light guided by the inner cladding. 3. The cladding light stripper of claim 1 , wherein the plurality of transversal notches have a pitch gradually varying along a length of the exposed section. 4. The cladding light stripper of claim 3 , wherein the pitch varies between 2 notches/cm and 200 notches/cm. 5. The cladding light stripper of claim 1 , wherein at least one of: respective depths of the plurality of transversal notches are between 5% and 20% of a diameter of the inner cladding, or respective depths of the plurality of transversal notches are between 20 micrometers to 80 micrometers deep. 6. The cladding light stripper of claim 1 , wherein respective depths of the plurality of transversal notches gradually vary along a length of the exposed section. 7. The cladding light stripper of claim 1 , wherein the plurality of transversal notches are spaced along a length and around a circumference of the exposed section. 8. The cladding light stripper of claim 1 , wherein the stripped portion is at least 40 mm in length. 9. The cladding light stripper of claim 1 , wherein the exposed section comprises a curved section having a bend radius of between 50 cm and 200 cm. 10. The cladding light stripper of claim 1 , further comprising; a heat sink for absorbing light that escapes the inner cladding and for dissipating heat produced by the absorbed light. 11. The cladding light stripper of claim 10 , wherein the heat sink forms a cavity around the stripped portion for intercepting the light escaped from the inner cladding, the cavity having an absorbing portion and a reflecting portion for directing the escaped light to the absorbing portion, wherein the absorbing portion is thermally connected to an external heat sink. 12. An optical fiber amplifier comprising: the cladding light stripper of claim 1 ; an amplifier double-clad optical fiber portion coupled to the double-clad optical fiber at a first end of the amplifier double-clad optical fiber portion, and a pump diode optically coupled to a second opposing end of the amplifier double-clad optical fiber portion, for providing pump light for propagation from the second end to the first end of the amplifier double-clad optical fiber portion. 13. The optical fiber amplifier of claim 12 , wherein the pump diode has a pump rating of at least 200 W, and the cladding light stripper has a light stripping efficiency of at least 15 dB. 14. A fiber laser comprising the optical fiber amplifier of claim 13 and an oscillator optically coupled thereto. 15. A method of forming the cladding light stripper of claim 1 , the method comprising; focusing a laser beam on the outer surface of the inner cladding in the exposed section to remove the inner cladding locally to form a transversal notch in the inner cladding; and repeating the focusing of the laser beam a plurality of times at different locations along the exposed section. 16. The method of claim 15 , wherein the double-clad optical fiber is moved, while repeating the focusing of the laser beam, to create consequent notches. 17. The method of claim 16 , wherein a CO 2 laser is used to generate the laser beam, the CO 2 laser is operated in a gated mode at a pulse duration of tens to hundreds of microseconds, and the laser beam is focused to optical power densities between 100 kW/cm 2 and 200 kW/cm 2 . 18. The method according to claim 17 , wherein the laser beam is focused to a focal spot size of 80 micrometers to 200 micrometers, and the focal spot is shaped, or the laser beam is angled, to produce a desired shape of the notch. 19. The method according to claim 15 , wherein repeating the focusing of the laser beam includes automatically controlling a spacing between adjacent notches using a computer-controlled translation stage for displacing the double-clad optical fiber lengthwise. 20. The cladding light stripper of claim 10 , wherein the heat sink is disposed adjacent the stripped portion of the double-clad optical fiber.