Slot-coupled CW standing wave accelerating cavity

What is claimed is: 1. A slot-coupled continuous wave (CW) graded beta standing wave accelerating cavity, comprising: a plurality of interconnected cells including a gap spacing, a cell length, a cone having a cone angle, a center bore, and a center axis extending longitudinally through the center bore; a wall between each of said interconnected cells; a plurality of non resonant coupling slots on the walls between said interconnected cells; said coupling slots in said walls are in axial alignment with a corresponding slot in the plurality of interconnected cells and are offset to a common side from the center axis of the accelerating cavity; the plurality of interconnected cells including a gap spacing and cell length that are varied throughout the length of the interconnected cells to accommodate varying beta and the cone angle is constant throughout the length of the interconnected cells; the interconnected cells include a center symmetric axis and the slots in each wall are axisymmetric about the center axis; and each of said coupling slots extends no more than an angle of 60 degrees around the center symmetric axis. 2. The slot-coupled CW standing wave accelerating cavity of claim 1 , further comprising an equator on each of said cells; and a cylindrical strip at each equator. 3. The slot-coupled CW standing wave accelerating cavity of claim 1 , wherein said slots are kidney-shaped. 4. The slot-coupled CW standing wave accelerating cavity of claim 1 , further comprising three or more of said slots on each of said walls. 5. The slot-coupled CW standing wave accelerating cavity of claim 2 , wherein each of said cells in said plurality of interconnected cells is of a different length for graded beta acceleration. 6. The slot-coupled CW standing wave accelerating cavity of claim 5 , wherein the width of the cylindrical strip is changed for different cells to vary the cell length. 7. The slot-coupled CW standing wave accelerating cavity of claim 1 , wherein the plurality of cells include a gap spacing and a cell length; the plurality of cells form a graded beta cavity; and the gap spacing and cell length are varied to accommodate varying beta and form a graded beta cavity. 8. The slot-coupled CW standing wave accelerating cavity of claim 7 , wherein each of the interconnected cells in the plurality of cells include a cone angle; and the cone angle is same for all cells. 9. The slot-coupled CW standing wave accelerating cavity of claim 1 , wherein each of said cells in said plurality of interconnected cells is of equal lengths for beta equal to 1 acceleration. 10. The slot-coupled CW standing wave accelerating cavity of claim 1 , further comprising an internal cooling channel in each wall. 11. The slot-coupled CW standing wave accelerating cavity of claim 1 , wherein the dimensions and geometry for the cell walls and slots are the same in each cell. 12. A method for high efficiency continuous wave (CW) graded beta acceleration, comprising: a. providing a particle accelerator including a plurality of interconnected cells of varying length separated by walls there between, the interconnected cells including a center symmetric axis, a gap spacing, a cell length, and a cone having a cone angle; b. providing a plurality of non resonant coupling slots on the walls between the interconnected cells to enable a pi-mode oscillating field; c. axially aligning the coupling slots in the walls along an axis parallel with and offset to a common side from the center symmetric axis; d. varying the gap spacing and cell length throughout the length of the interconnected cells to accommodate varying beta; e. maintaining a constant cone angle throughout the interconnected cells; and f. limiting the extent of each of said coupling slots to no more than an angle of 60 degrees around the center symmetric axis. 13. The method of claim 12 , further comprising providing a gap spacing between the interconnected cells; and varying the gap spacing between the cells accommodate varying beta and form a graded beta cavity. 14. The method of claim 12 , further comprising providing an internal cooling channel in each wall. 15. The method of claim 12 , further comprising providing a cone having a cone angle on each of said cells; and setting the cone angle the same for all cells.