MaximumPC 2007 02

r & d BREAKING DOWN TECH —PRESENT AND FUTURE

60 MAXIMUMPC FEBRUARY 2007

B

ut Stephenson doesn’t get all the credit

for this idea: The technology—formally

known as electrophoretic display—was

conceived of in the 1970s. Research efforts

were pretty much abandoned in the face

of what seemed to be insurmountable

challenges, however, until a group of MIT

students under the tutelage of Professor

Joseph Jacobson made a key breakthrough

in the 1990s.

Jacobson later founded E Ink to commer-

cialize the technology. Today, E Ink’s product

can be found in everything from Sony’s Reader

(a handheld electronic book) to Motorola’s

new Motofone (a cell phone that’s thinner and

lighter—by half—than the company’s Razr, yet

delivers 500 minutes of talk time).

Electrophoretic displays operate by

moving tiny electrically charged particles of

pigment in a liquid sandwiched between two

conductive plates. When voltage is applied

across the two plates, negatively charged

particles migrate to the plate exhibiting

positive polarity, while positively charged

particles migrate to a negatively charged

plate on the opposite side. If the white-

pigmented particles bear a negative

charge and a negative electrical charge

is applied to the bottom plate, the white

particles will move to the top (view-

ing) plate and become visible. Black

particles bearing the opposite charge,

meanwhile, are drawn to the bottom

plate and become hidden. Reversing

the charge has the opposite effect.

FAILURE ANALYSIS

Three phenomena were responsible

for the failure of earlier prototypes:

gravity, adhesion, and fl uid con-

vection. Since the particles are

denser than the liquid they fl oat in,

gravity would eventually overcome

electrical attraction and the par-

ticles would sink to the bottom of

the display. Some particles would

inevitably adhere to the surfaces of the con-

ductive plates, resisting the forces of both

gravity and electrical attraction. And fl uid

convection—the dynamic of some particles

boiling up to the top when voltage is applied

to the plates, while others migrate to the

bottom—rendered the displays too slow.

EUREKA!

The breakthrough came when the MIT stu-

dents encased ceramic pigment particles

in microcapsules. Microencapsulation has

been used for timed-release drug delivery

and other purposes for decades, but most

microcapsules are designed to break down

over time. E Ink’s microcapsules act as

durable containers in which the pigment par-

ticles are suspended in organic oil; the black

particles are made of the pigment used in

newspaper ink, while the white particles are

made of the pigment used to create white

paint. Since each microcapsule is less than

50 microns in diameter, the particles don’t

settle because they can migrate only as far

as the bottom of the microcapsule; they

don’t stick to the surfaces of the microcap-

sule, and the microcapsules are so small

that the particles contained within them are

not subject to fl uid convection.

The next step in the process is to mix

the microcapsules with additional polymers

to create a paste. E Ink rolls out a fl exible

plastic substrate with an adhesive backing,

applies the paste to the other side, allows

it to dry, and then rolls it up on a second

White Paper: Electronic Paper

Each 50-micron microcapsule contains organic oil and approximately one million negatively charged black-pigment particles and

positively charged white ones. When a positive charge is applied to the electrodes, the white particles fl oat to the top and become

visible, while the black particles sink to the bottom and are hidden.

HOW IT WORKS

Top transparent

electrode

E Ink technology

ILLUSTRATION COURTESY E INK CORPORATION

We’ve been jonesin’ for

electronic paper ever

since we read Neal

Stephenson’s 1992 sci-fi

novel The Diamond Age.

BY MICHAEL BROWN

Positively

charged

white

pigment

chips

Clear

fl uid

Subcapsule addressing enables

supercrisp display capability

Negatively

charged

black

pigment

chips

Bottom

electrode

Negatively

charged

black

pigment

chips

Bottom

electrode

LIGHT STATE DARK STATE

+ + + - - -

Electrophoretic displays operate by

moving tiny electrically charged particles of

pigment in a liquid sandwiched between two

conductive plates. When voltage is applied

across the two plates, negatively charged

particles migrate to the plate exhibiting

positive polarity, while positively charged

particles migrate to a negatively charged

plate on the opposite side. If the white-

pigmented particles bear a negative

charge and a negative electrical charge

is applied to the bottom plate, the white

particles will move to the top (view-

ing) plate and become visible. Black

particles bearing the opposite charge,

meanwhile, are drawn to the bottom

plate and become hidden. Reversing

the charge has the opposite effect.

MAMAMAXIMXIMXIMXIMUUUUMMPPPCCFEBRUARY 2007

Sony’s Reader uses

E Ink’s technology.