Distributed Coupling and Multi-Frequency Microwave Accelerators

1 . A microwave circuit for a linear accelerator, the microwave circuit comprising multiple metallic cell sections, a pair of distribution waveguide manifolds, and a sequence of feed arms connecting the manifolds to the cell sections; wherein the distribution waveguide manifolds are connected to the cell sections so that alternating pairs of cell sections are connected to opposite distribution waveguide manifolds, wherein the distribution waveguide manifolds have concave modifications of their walls opposite the feed arms, and wherein the feed arms have portions of two distinct widths. 2 . The microwave circuit of claim 1 wherein coupling geometry to each cell section is implemented with a three port network, wherein the three port network is adapted such that a dependence of the accelerator cavity design on a distribution manifold circuit parameter is minimized. 3 . The microwave circuit of claim 2 wherein the three port network is an E-plane junction, and wherein the waveguide manifolds and three-port network are formed from two parts joined along the E-plane. 4 . The microwave circuit of claim 1 wherein the distribution waveguide manifolds are connected to the cell sections by two different types of junctions adapted to allow two frequency operation. 5 . The microwave circuit of claim 1 wherein each distribution waveguide manifold is composed of identical units, whereby power may be distributed evenly between accelerator structures. 6 . The microwave circuit of claim 1 wherein the distribution waveguide matches a set of standing wave accelerator structures and allows for reflected power be output to external loads. 7 . A method of manufacturing a microwave circuit for a linear accelerator, the method comprising making two quasi-identical parts, and joining the two parts to form the microwave circuit, wherein the microwave circuit comprises multiple metallic cell sections, a pair of distribution waveguide manifolds, and a sequence of feed arms connecting the manifolds to the cell sections; wherein the distribution waveguide manifolds are connected to the cell sections so that alternating pairs of cell sections are connected to opposite distribution waveguide manifolds, thereby allowing for many manufacturing techniques including electron beam welding, and thereby allowing the use of un-annealled copper alloys, and hence greater tolerance to high gradient operation. 8 . The method of claim 7 wherein the distribution waveguide manifolds have concave modifications of their walls opposite the feed arms, and wherein the feed arms have portions of two distinct widths.