emit light. Emissive OLED displays do not require
backlighting and are viewable at oblique angles.
They are also transparent; red, green, and blue layers
can be stacked such that a full-color (RGB) pixel is a
fully color-mixed single pixel with depth, rather than
a closely spaced planar cluster of pixels as in traditional CRT and LCD displays.
OLEDs are commercially available today in a
mass market of smaller displays (such as in car
stereos, MP3 players, and cell phones). More innovative use of the technology awaits the streamlining of
manufacturing methods; for example, flexible display screens are being developed using plastic substrates (such as thin polyester films and bendable
metallic foils). Technology demonstrations by a
number of companies, including Polymer Vision
( polymervision.com), feature devices with rollable
displays (see Figure 1). Taking the concept a step further, we anticipate development of large, flexible display interfaces that bend, flex, and conform to many
surfaces.
OLED technology is also a focus of interest as a
path to energy-efficient solid-state lighting. Since
organic polymer layers can be manufactured as large-area active elements, it is possible to combine area
color, shape, and flexibility to create novel interactive
objects and interfaces. For instance, researchers at
General Electric Global Research ( www.ge.com/
research/) anticipate light-emissive curtains and wallpapers.
Electrophoretic displays (EPDs), often associated
with the brand name E-Ink ( www.eink.com/), are
marketed as alternatives to traditional flexible paper.
One type of particle display, “electronic ink,” consists of thousands of microcapsules deposited onto a
substrate. Each microcapsule contains positively
charged white particles and negatively charged black
particles suspended in a clear fluid. When a negative
electric field is applied, the white particles move to
the top of the microcapsule, causing that “pixel” to
appear white and vice versa (see Figure 1). The
microcapsules are bi-stable, meaning that once configured as black or white, no further energy is
required to maintain their state. As with OLED,
flexibility is achieved through the use of flexible substrates (plastic) and conductors (metal foil or printed
conductive traces).
Applications of E-Ink are primarily as a paper
substitute in traditionally monochrome paper-based
media (such as signage and e-books) but also include
irregularly shaped and flexible displays. For example,
the Seiko Watch Corporation ( www.seikowatches.
com) has produced a limited run of unique watches
based on a small, flexible E-Ink display. E-Ink also
prototyped various color displays and demonstrated
multicolor EPDs using color filters [ 2].
In addition to even newer technologies still
being developed and refined, existing technologies offer some of their benefits in the form of
displays or light-emitting materials. For example, electroluminescent lighting (EL) is a technology through which thin, flexible lamps are
produced via an industrial printing process. A layer
of phosphor is sandwiched between two conductive
layers, illuminating when an alternating electrical
current is applied across the layers. EL is widely used
in backlighting applications for portable electronics,
as well as for large-surface-area applications. Manufactured EL panels can be cut into irregular shapes,
as well as printed onto, lending themselves to advertising and signage.
At www.aeolab.com, we have applied the materials and processes used in the manufacturing of commercial electroluminescent panels to hand-print
custom-designed light panels on paper and fabric
within a studio environment. The Puddlejumper
raincoat ( www.mintymonkey.com/puddlejumper
_p1.html) developed by Elise Co features EL panels
silk-screened onto flexible fabric and activated via
water-droplet sensors printed with conductive inks
(see Figure 2).
In addition to flat panels, EL lamps are also manufactured as wire elements and packaged in clear
plastic tubing of varying diameters. In this form, the
material is well-suited to creative manipulation as a
fiber, combined with other materials or integrated
directly into textiles with either a woven or knitted
structure. Artists and designers have used EL wire to
make light-emitting artifacts ranging from garments
to lamps to spatial installations (such as Loop’s
Sonumbra ( www.loop.ph), a net-like illuminated
canopy.
Optical fiber is another product that can be used
creatively as a material for lighting and display. Specially treated “side-emitting” fibers (with outer coatings that diffuse light along the length of the strand
rather than reflecting it perfectly within the interior
core) are produced in thicknesses of up to a quarter
of an inch. Strands of such fiber are woven into fabric and embedded into other materials, then coupled
with light sources at the fiber ends to create unique
textile and flexible-display surfaces. These integra-
