Fluid ejection device with mixing beads

What is claimed is: 1. A fluid ejection device comprising: a die substrate; a chiclet adhered by a front side thereof to the die substrate; an ink delivery slot formed through the chiclet from a back side thereof to the front side thereof; a mixing bead at the back side of the chiclet, adjacent the ink delivery slot; and at least one electromagnet on at least one side of the ink delivery slot to raster the mixing bead back and forth across the ink delivery slot away from and toward the at least one side. 2. A fluid ejection device as in claim 1 , wherein the at least one electromagnet comprises two electromagnets, one on each side of the ink delivery slot to raster the mixing bead back and forth across the ink delivery slot through alternating activation of the two electromagnets. 3. A fluid ejection device as in claim 1 , wherein the mixing bead comprises a magnet, wherein the at least one electromagnet comprises two electromagnets, one on each side of the ink delivery slot to raster the mixing bead back and forth across the ink delivery slot through simultaneous activation of the two electromagnets. 4. A fluid ejection device as in claim 1 , wherein the at least one electromagnet comprises a single electromagnet on one side of the ink delivery slot to raster the mixing bead back and forth across the ink delivery slot through reversing a direction of current flow through a coil of the electromagnet. 5. A fluid ejection device as in claim 3 , wherein simultaneous activation of the two electromagnets comprises alternating the polarities of the two electromagnets with each activation. 6. A fluid ejection device as in claim 1 , wherein the mixing bead comprises a metal bead. 7. A fluid ejection device as in claim 6 , wherein the metal bead is formed of a ferromagnetic material selected from the group consisting of iron, nickel, cobalt, and metal alloy. 8. A fluid ejection device as in claim 1 , wherein the mixing bead comprises a magnet. 9. A fluid ejection device as in claim 1 , wherein the mixing bead is sized such that the mixing bead cannot enter the ink delivery slot. 10. A fluid ejection device as in claim 1 , further comprising a polymer layer coating the mixing bead. 11. A processor-readable medium, storing code representing instructions that when executed by a processor cause the processor to: turn on first and second electromagnets in a fluid ejection device to raster a mixing bead back and forth across an ink delivery slot away from and toward the first and second electromagnets; wherein the first electromagnet is located at a first side of the ink delivery slot and the second electromagnet is located at a second side of the ink delivery slot. 12. A processor-readable medium as in claim 11 , wherein turning on the electromagnets comprises: turning on the first electromagnet; turning off the first electromagnet; and upon turning off the first electromagnet, turning on the second electromagnet. 13. A processor-readable medium as in claim 11 , wherein the mixing bead is a magnet, and turning on the electromagnets comprises turning on the first and second electromagnets simultaneously such that the first electromagnet pulls the mixing bead in a first direction toward the first electromagnet while the second electromagnet pushes the mixing bead in the first direction away from the second electromagnet. 14. A processor-readable medium storing code representing instructions that when executed by a processor cause the processor to: turn on a single electromagnet located at a first side of an ink delivery slot in a fluid ejection device, such that the single electromagnet has a first polarity; and turn on the single electromagnet such that the single electromagnet has a reverse polarity, wherein turning on the single electromagnet to have the first polarity and turning on the single electromagnet to have the reverse polarity is to raster a mixing bead back and forth across the ink delivery slot away from and toward the single electromagnet. 15. A processor-readable medium as in claim 14 , wherein: turning on the single electromagnet to have the first polarity comprises applying electric current to a coil of the electromagnet in a first direction; and turning on the single electromagnet to have the reverse polarity comprises applying the electric current to the coil in a reverse direction.