System and method for treating surface of media with a digitally addressable dryer array to reduce moisture gradient and media cockle

What is claimed is: 1. A printer comprising: at least one printhead having a plurality of inkjets configured to eject ink; a dryer having an array of radiators and at least two vent openings, the array of radiators having a plurality of rows of radiators extending in a direction parallel to a process direction and a plurality of columns of radiators extending in a cross-process direction perpendicular to the process direction, each radiator configured to heat an area opposite the radiator at a predetermined distance, and the at least two vent openings being separated from one another in the process direction by a predetermined distance, each vent opening being configured to enable a flow of fluid to cool the array of radiators; a blower configured to send a flow of fluid to one of the at least two vent openings and to receive the flow of fluid from the other of the at least two vent openings; a media transport configured to move media past the at least one printhead to enable a surface of the media to receive ink ejected by the plurality of inkjets in the at least one printhead and to move the media in the process direction past the dryer to enable portions of the surface of the media to be heated by the radiators in the array of radiators; and a controller operatively connected to the at least one printhead, the dryer, the blower, and the media transport, the controller being configured to operate the plurality of inkjets in the at least one printhead to eject ink onto the surface of the media to form an image on the surface of the media, to operate the media transport to move the media past the at least one printhead and the dryer, to activate selectively the radiators in the array of radiators to heat the portions of the surface of the media on which ink has been ejected, and to operate the blower to circulate the flow of fluid through the at least two vent openings to cool the array of radiators. 2. The printer of claim 1 , the controller being further configured to: activate each radiator in the array of radiators in response to any portion of the surface of the media onto which ink has been ejected being opposite the radiator. 3. The printer of claim 2 , the controller being further configured to: deactivate each radiator in the array of radiator in response to the portion of the surface of the media onto which ink has been ejected is no longer opposite the radiator. 4. The printer of claim 1 , the at least two vent openings further comprising: a first plurality of vent openings extending in a column in the cross-process direction; and a second plurality of vent openings extending in a row in the process direction. 5. The printer of claim 1 further comprising: at least one image sensor configured to generate signals corresponding to the surface of the media; and the controller is operatively connected to the at least one image sensor to receive the signals generated by the at least one image sensor and the controller being further configured to activate and deactivate the radiators in the array of radiators with reference to the signals received from the at least one image sensor. 6. The printer of claim 5 wherein the at least one image sensor is at least one photo detector. 7. The printer of claim 1 wherein each radiator in the array of radiators is an infrared emitter. 8. The printer of claim 7 wherein each infrared emitter in the array of radiators is an LED infrared emitter configured to generate electromagnetic radiation having a wavelength in a range of about two to about three microns. 9. A method of operating a printer comprising: operating with a controller at least one printhead having a plurality of inkjets to eject ink to media; operating with the controller a media transport to move the media in a process direction past a dryer including an array of radiators to receive heat from the array of radiators, the array of radiators having a plurality of rows of radiators extending in a direction parallel to a process direction and a plurality of columns of radiators extending in a cross-process direction perpendicular to the process direction; operating with the controller the dryer to selectively activate at least one of the radiators to direct heat to the media with respect to image data of the image formed on the media; and operating with the controller a fan to circulate fluid through at least two vent openings in the dryer to cool the array of radiators, the at least two vent holes being spaced with respect to the process direction. 10. The printer of claim 9 further comprising: operating with the controller the dryer with respect to image data to direct heat to the portion of the media containing the image by operating the controller to activate each radiator having a corresponding heat zone containing a portion of the media with at least a portion of the formed image. 11. The printer of claim 10 further comprising: operating with the controller the dryer to selectively activate each radiator when the portion of the media containing the portion of the formed image enters the corresponding heat zone. 12. The printer of claim 10 further comprising: operating with the controller the dryer to selectively deactivate the radiators after the portion of the media containing the formed image passes through the respective heat zone. 13. The printer of claim 9 , further comprising: operating with the controller a fan to circulate fluid through a first plurality of vent openings extending in a column in the cross-process direction and a second plurality of vent openings spaced with respect to the process direction and extending in a column in the cross-process direction. 14. The printer of claim 9 further comprising: operating with the controller at least one image sensor to generate signals corresponding to image data of the image formed on the media. 15. The printer of claim 9 wherein: operating with the controller at least one photo detector to generate signals corresponding to image data of the image formed on the media. 16. The printer of claim 9 wherein operating the plurality of radiators comprises operating a plurality of infrared emitters. 17. The printer of claim 16 wherein operating the plurality of infrared emitters comprises operating a plurality of LED infrared emitters to generate electromagnetic radiation having a wavelength of 2-3 microns.