Emission surface for an X-ray device

The invention claimed is: 1. An electron emitter comprising: a surface comprising a round emission area which is a circle capable of emitting electrons when heated, wherein the round emission area comprises slots that separate segments from one another and define a radial electrical path; and at least one of a gap, a channel, or a combination thereof that separates a first portion of the round emission area from a second portion of the round emission area and permits thermal expansion of the first portion and the second portion within the at least one gap or channel without permitting the first portion and the second portion to touch one another wherein the radial electrical path begins at an outer diameter of the circle at the first portion and follows a pathway through the first portion to the center of the circle before entering the second portion, further comprising at least a second gap or channel orthogonal to the at least one gap or channel and divides the first portion and the second portion into equal portions that form at least four quadrants; two electrically conductive legs coupled to the surface at respective locations outside the round emission area and that are capable of supplying current to the round emission area; and at least one leg not electrically conductive and couple to the electron emitter to provide structural support and hold the electron emitter in-plane within at least two planes. 2. The electron emitter of claim 1 , wherein the first portion and the second portion are separate areas that form quadrants. 3. The electron emitter of claim 2 , wherein a diameter of the circle is at least 7 mm. 4. The electron emitter of claim 2 , wherein the round emission area comprises at least one v-shaped gap that narrows towards a center of the circle. 5. The electron emitter of claim 4 , wherein the v-shaped gap narrows from a widest gap length that is about twice a narrowest gap length. 6. The electron emitter of claim 4 , wherein the surface comprises both a v-shaped gap and a channel. 7. The electron emitter of claim 1 , wherein the round emission area comprises at least two v-shaped gaps. 8. The electron emitter of claim 1 , wherein the gap, the channel, or the combination thereof, bisects the surface and extends past the round emission area into a wider notch that terminates at an end of a longest dimension of the electron emitter. 9. The electron emitter of claim 1 , wherein the round emission area comprises a hole at a midpoint of the round emission area. 10. The electron emitter of claim 1 , wherein the emitter comprises tungsten hafnium carbide or a combination thereof. 11. An electron emitter comprising: a surface comprising a disc-shaped emission area separated into quadrants and capable of emitting electrons when heated with a driving current of 10 A or less; and two electrically conductive legs coupled to the surface at respective locations outside the disc-shaped emission area and that are capable of supplying current to the disc-shaped emission area such that, when current is applied to the disc-shaped emission area, the disc-shaped emission area heats to a temperature of at least 2000 degrees Celsius with a temperature variation across the emission surface of less than 6% of a maximum temperature achieved when the disc-shaped emission area is heated; and a non-electrically conductive leg coupled to the surface to provide structural support to hold the electron emitter in-plane; and at least one leg not electrically conductive and couple to the electron emitter to provide structural support and hold the electron emitter in-plane within at least two planes. 12. The electron emitter of claim 11 , wherein the disc-shaped emission area comprises a circle. 13. The electron emitter of claim 12 , wherein a diameter of the circle is at least 7 mm. 14. The electron emitter of claim 12 , wherein a diameter of the circle is between about 7 mm and about 11 mm. 15. The electron emitter of claim 12 , wherein the emitter comprises an annular region surrounding the emission surface that is not part of the emission surface. 16. The electron emitter of claim 11 , wherein the disc-shaped emission area comprises an ellipse. 17. The electron emitter of claim 11 , wherein the disc-shaped emission area heats to a temperature of at least 2000 degrees Celsius with a temperature variation across the emission surface of less than 6% of a maximum temperature achieved at a driving current between about 7.5 A and about 9.5 A. 18. An X-ray tube comprising: an electron beam source comprising an electron emitter configured to emit an electron beam, wherein the electron emitter comprises: a disc-shaped emission area comprising at least a first portion and a second portion, and capable of emitting electrons when heated, and further comprising a serpentine electrical path wherein the serpentine electrical path extends from an outer diameter of the disc-shaped emission area at the first portion to a center of the disc-shaped emission area before entering the second portion; further comprising at least a second gap or channel orthogonal to the at least one gap or channel and dividing the first portion and the second portion into equal portions that form at least four quadrants; and a plurality of electrically conductive legs coupled to the electron emitter at respective locations outside the disc-shaped emission area and that are capable of supplying current to the disc-shaped emission area; and a post not electrically conductive and coupled to the electron emitter to form a three-post arrangement that holds the electron emitter in-plane within at least two planes; an anode assembly configured to receive the electron beam and to emit X-rays when impacted by the electron beam; and a housing in which the electron beam source and the anode assembly are disposed. 19. The X-ray tube of claim 18 , wherein the disc-shaped emission area comprises a circle having a diameter greater than about 7 mm. 20. The X-ray tube of claim 19 , wherein the disc-shaped emission area comprises at least one v-shaped gap that narrows towards a center of the circle, separate from and partially separates portions of the disc-shaped emission area. 21. The X-ray tube of claim 20 , wherein the disc-shaped emission area comprises a hole at a center of the circle independent from the v-shaped gaps to facilitate regulating temperature. 22. The X-ray tube of claim 18 , wherein the disc-shaped emission area comprises a plurality of lobes. 23. The X-ray tube of claim 22 , wherein at least a portion of the plurality of lobes are separated by one or more V-shaped gaps and wherein the disc-shaped emission area is configured to expand within the one or more V-shaped gaps when heated such that the one or more V-shaped gaps decreases in size without permitting adjacent lobes to touch one another.