Absorber for wakefield interference management at the entrance of the wiggler of a free electron laser

What is claimed is: 1. A method for managing reflected wake field energy in the form of broad band microwave and TeraHertz (THz) radiation in a free electron laser (FEL) having a wiggler producing laser light and containing a cookie-cutter for shaping the wake field wave to the wiggler chamber aperture, comprising: a nose portion on the upstream end of the cookie-cutter, the nose portion including two flat surfaces, a planar face on the cookie-cutter perpendicular to each of the flat surfaces, and a slot in the nose portion in axial alignment with the wiggler chamber aperture; and covering the planar faces of the cookie-cutter with a broadband microwave and TeraHertz (THz) radiation absorber wherein the absorber is a non-porous pyrolytic grade of graphite with small grain size. 2. The method for managing broadband microwave and TeraHertz (THz) radiation of claim 1 wherein the graphite includes a porosity of between 10 and 20%. 3. The method for managing broadband microwave and TeraHertz (THz) radiation of claim 1 wherein the graphite includes an average grain size of between 5 and 20 μm. 4. The method for managing broad band microwave and TeraHertz (THz) radiation of claim 1 wherein the planar faces of the cookie-cutter are of semi-circular shape and the broad band microwave and TeraHertz (THz) radiation absorbers are in the shape of semi-circular disks. 5. The method for managing the broad band microwave and TeraHertz (THz) radiation of claim 4 wherein the semi-circular disks further comprise: a flat side; and an arcuate side. 6. The method for managing the broad band microwave and TeraHertz (THz) radiation of claim 5 wherein the semi-circular disks further comprise: a planar upstream surface; a planar downstream surface; and a plurality of bolt holes therein. 7. The method for managing the broad band microwave and TeraHertz (THz) radiation of claim 4 further comprising: providing a vacuum chamber boundary and a two-sided bimetallic CF flange having a copper central portion; and conveying absorbed heat beyond the vacuum chamber boundary by attaching the copper central portion of the two-sided, bimetallic CF flange to the cookie-cutter. 8. The method for managing broad band microwave and TeraHertz (THz) radiation of claim 1 wherein the cookie-cutter is machined from a single piece of oxygen-free high conductivity (OFHC) copper. 9. The method for managing broadband microwave and TeraHertz (THz) radiation of claim 1 further comprising a means of shaping the wake field wave of the electron pulse through the wiggler. 10. The method for managing broad band microwave and TeraHertz (THz) radiation of claim 6 wherein the means of shaping the wake field wave of the electron pulse through the wiggler includes providing the slot in the nose portion with a width that is at least 3 times the height of the slot. 11. The method for managing the broad band microwave and TeraHertz (THz) radiation of claim 1 further comprising: a planar downstream surface on the THz absorber; and a sheet of indium foil sandwiched between the planar downstream surface of the THz absorber and the corresponding planar face of the cookie-cutter.