We demonstrate print-deposition of high resolution, patterned, multicolored thin films of luminescent colloidal quantum dot (QD)-polymer composites and use the printed patterns in fabricating robust, bright, full-color AC-driven displays. The benefits of AC electroluminescent (EL) displays include simple, low-cost fabrication and high reliability; however, finding efficient and stable phosphors for full-colored displays remains a major challenge.[1] Today, red-, green-, and blue-light-emitting (RGB) phosphors for AC-EL comprise different material systems and can have luminous efficiencies that span an order of magnitude, rendering manufacture of a multicolor display with balanced RGB components difficult. [1][2][3] While there has been substantial research on stacked and patterned devices, one of the most feasible strategies for realizing RGB AC-EL displays is color filtering of white, ZnS-based phosphors. [1,2] Filtering, however, wastes up to 90% of the output optical power to achieve color saturation, which requires that the display be operated at ten times video brightness in order to meet the RGB color standard. [4] This results in greater power consumption, faster pixel degradation, and shorter display lifetimes.[1]To achieve full-color AC-EL displays, in this study we use colloidally synthesized QDs to print patterns of robust, solution-processable, luminescent light-converting thin films for AC-EL displays. QDs offer narrow-band luminescence that can be tuned across the visible spectrum by varying their size and chemical composition. [5] This property motivated the use of QD luminescent centers in thin-film light-emitting diode (LED) structures, in which QDs were electrically excited to demonstrate low-power, color-saturated devices, with side-by-side patterning of RGB pixels enabled by microcontact printing of the QD layers. [6] In alternate device designs, QDs can also be optically excited, where, for example, the small Stokes shift of red-and green-light-emitting QDs enables their optical excitation by blue light. This property of QDs led to the demonstration of optical down-conversion using blue GaN LEDs to excite QDs in polylaurylmethacrylate (PLMA), and the generation of point sources of saturated-color light. [7] In the present work, we demonstrate a planar, full-color AC-EL display that comprises luminescent thin films of QDs that absorb blue electroluminescence from a commercial phosphor powder and then emit photons at a longer wavelength characteristic of the QD band gap. Figure 1. a) Absorption and photoluminescence spectra of spin-coated thin films of red and green QDs and the electroluminescence spectrum of the blue-phosphor paste powered by 50 kHz AC excitation demonstrate the spectral overlaps needed to achieve optical down-conversion of phosphor emission to QD-film luminescence. The inset schematic depicts the crosssection of an AC powder EL device structure with QD-PIB pixels. b) 1 mm profilometry scan of the edge of a green rectangular pixel measuring 3 mm  5 mm demonstrates the edg...
