System and method for producing high quality images with aqueous inks in a printer

What is claimed is: 1. A printer comprising: a first printhead operatively connected to a source of aqueous ink having a first color, the first printhead being configured to eject the aqueous ink having the first color onto a substrate as the substrate passes the first printhead in a process direction; a first source of infrared (IR) radiation following the first printhead in the process direction, the first source of IR radiation being tuned to heat color pigment particles in the aqueous ink having the first color; a second printhead operatively connected to a source of aqueous ink having a second color that is different than the first color, the second printhead following the first source of IR radiation in the process direction and being configured to eject the aqueous ink having the second color onto the substrate after the substrate has passed the first printhead and the first source of IR radiation; and a second source of IR radiation following the second printhead in the process direction, the second source of IR radiation being tuned to heat color pigment particles in the aqueous ink having the second color and not heat color pigment particles in the aqueous ink having the first color. 2. The printer of claim 1 further comprising: a third printhead operatively connected to a source of aqueous ink having a third color that is different than the first color and the second color, the third printhead following the second source of IR radiation in the process direction and being configured to eject the aqueous ink having the third color onto the substrate after the substrate has passed the second printhead and the second source of IR radiation; and a third source of IR radiation following the third printhead in the process direction, the third source of IR radiation being tuned to heat color pigment particles in the aqueous ink having the third color and not heat color pigment particles in the aqueous ink having the first color and not heat color pigment particles in the aqueous ink having the second color. 3. The printer of claim 2 further comprising: a fourth printhead operatively connected to a source of aqueous ink having a fourth color that is different than the first color, the second color, and the third color, the fourth printhead following the third source of IR radiation in the process direction and being configured to eject the aqueous ink having the fourth color onto the substrate after the substrate has passed the third printhead and the third source of IR radiation; and a fourth source of IR radiation following the fourth printhead in the process direction, the fourth source of IR radiation being tuned to heat color pigment particles in the aqueous ink having the fourth color and not heat color pigment particles in the aqueous ink having the first color and not heat color pigment particles in the aqueous ink having the second color and not heat color pigment particles in the aqueous ink having the third color. 4. The printer of claim 3 wherein the first color is black, the second color is cyan, the third color is magenta, and the fourth color is yellow; and the first source of IR radiation emits infrared radiation in a range of about 375 nm to about 650 nm; the second source of IR radiation emits infrared radiation in a range of about 575 nm to about 650 nm; the third source of IR radiation emits infrared radiation in a range of about 475 nm to about 515 nm; and the fourth source of IR radiation emits infrared radiation in a range of about 375 nm to about 425 nm. 5. The printer of claim 4 wherein each source of IR radiation is a light emitting diode (LED) that emits IR radiation. 6. The printer of claim 5 further comprising: an optical sensor positioned in the process direction after the substrate has passed the fourth source of IR radiation, the optical sensor being configured to generate image data of printed images on the substrate; and a controller operatively connected to the optical sensor, the controller being configured to detect whether ink drop spread for the ink drops ejected by the first printhead, the second printhead, the third printhead, or fourth printhead is whether a predetermined range. 7. The printer of claim 6 wherein the controller is further configured to: increase an intensity of the infrared radiation emitted by one of the first LED IR radiation source, the second LED IR radiation source, the third LED IR radiation source, and the fourth LED IR radiation source when the ink drop spread for the ink drops emitted by one of the first LED IR radiation source, the second LED IR radiation source, the third LED IR radiation source, and the fourth LED IR radiation source exceeds the predetermined range; and decrease an intensity of the infrared radiation emitted by one of the first LED IR radiation source, the second LED IR radiation source, the third LED IR radiation source, and the fourth LED IR radiation source when the ink drop spread for the ink drops emitted by one of the first LED IR radiation source, the second LED IR radiation source, the third LED IR radiation source, and the fourth LED IR radiation source is less than the predetermined range. 8. The printer of claim 4 wherein the fourth source of IR radiation emits white light. 9. The printer of claim 4 , the fourth source of IR radiation further comprising: a fifth source of IR radiation that emits infrared radiation in a range of about 575 nm to about 650 nm; a sixth source of IR radiation that emits infrared radiation in a range of about 475 nm to about 515 nm; and a seventh source of IR radiation that emits infrared radiation in a range of about 375 nm to about 425 nm. 10. A method for operating a printer comprising: operating a first printhead operatively connected to a source of aqueous ink having a first color to eject the aqueous ink having the first color onto a substrate as the substrate passes the first printhead in a process direction; operating a first source of infrared (IR) radiation following the first printhead in the process direction, the first source of IR radiation being tuned to heat color pigment particles in the aqueous ink having the first color; operating a second printhead operatively connected to a source of aqueous ink having a second color that is different than the first color to eject the aqueous ink having the second color onto the substrate after the substrate has passed the first printhead and the first source of IR radiation; and operating a second source of IR radiation following the second printhead in the process direction, the second source of IR radiation being tuned to heat color pigment particles in the aqueous ink having the second color and not heat color pigment particles in the aqueous ink having the first color. 11. The method of claim 10 further comprising: operating a third printhead operatively connected to a source of aqueous ink having a third color that is different than the first color and the second color to eject the aqueous ink having the third color onto the substrate after the substrate has passed the second printhead and the second source of IR radiation; and operating a third source of IR radiation following the third printhead in the process direction, the third source of IR radiation being tuned to heat color pigment particles in the aqueous ink having the third color and not heat color pigment particles in the aqueous ink having the first color and not heat color pigment particles in the aqueous ink having the second color. 12. The method of claim 11 further comprising: operating a fourth printhead operatively connected to a source of aqueous ink having a fourth color that is differe