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Silicon chips stretch into shape

2008-03-28 07:11:09

By Jonathan Fildes

Science and technology reporter, BBC News

Normally fragile and brittle silicon chips have been made to bend and fold,

paving the way for a new generation of flexible electronic devices.

The stretchy circuits could be used to build advanced brain implants, health

monitors or smart clothing.

The complex devices consist of concertina-like folds of ultra-thin silicon

bonded to sheets of rubber.

Writing in the journal Science, the US researchers say the chip's performance

is similar to conventional electronics.

"Silicon microelectronics has been a spectacularly successful technology that

has touched virtually every part of our lives," said Professor John Rogers of

the University of Illinois at Urbana-Champaign, one of the authors of the

paper.

But, he said, the rigid and fragile nature of silicon made it very unattractive

for many applications, such as biomedical implants.

"In many cases you'd like to integrate electronics conformably in a variety of

ways in the human body - but the human body does not have the shape of a

silicon wafer."

We had to figure out how to make the entire circuit in an ultra-thin format

John Rogers

Professor Zhenqiang Ma of the University of Wisconsin-Madison, who also works

on flexible silicon circuitry, said the new research was an "important step".

"Completely integrated, extremely bendable circuits have been talked about for

many years but have not been demonstrated before," he told BBC News. "This is

the first one."

Silicon wave

The chips build on previous work by Professor's Roger's lab.

In 2005, the team demonstrated a stretchable form of single-crystal silicon.

BUILDING BENDABLE CHIPS

1. Plastic sheet is bonded to a rigid substrate with adhesive

2. Complex circuits are built using conventional silicon fabrication techniques

3. Adhesive is dissolved, allowing circuits embedded on plastic sheet to be

peeled away

4. Sheet is bonded to pre-strained rubber, creating bendable silicon chips

"That demonstration involved very thin narrow strips of silicon bonded to

rubber," explained Professor Rogers.

At a microscopic level these strips had a wavy structure that behaved like

"accordion bellows", allowing stretching in one direction.

"The silicon is still rigid and brittle as an intrinsic material but in this

accordion bellows geometry, bonded to rubber, the overall structure is

stretchable," he told BBC News.

Using the material, the researchers were able to show off individual, flexible

circuit components such as transistors.

The new work features complete silicon chips, known as integrated circuits

(ICs), which can be stretched in two directions and in a more complex fashion.

"In order to do this, we had to figure out how to make the entire circuit in an

ultra-thin format," explained Professor Rogers.

The team has developed a method that can produce complete circuits just one and

a half microns (millionths of a metre) thick, hundreds of times thinner than

conventional silicon circuits found in PCs.

"What that thinness provides is a degree of bendability that substantially

exceeds anything we or anyone else has done at circuit level in the past," he

said.

Rubber wrinkle

The slim line circuits, like conventional chips, are made of sandwiches of

multiple materials to form the wires and different components. The depth and

relative position of the different layers, including chromium, gold and

silicon, is crucial.

"You have to design the thicknesses of those materials in such a way that you

put what is called the neutral mechanical plane so that it overlaps with the

most brittle material," explained Professor Rogers.

The neutral mechanical plane is the layer in a material where there is zero

strain.

In a homogenous substance, this plane occurs exactly half way between the top

and bottom surface, where there is equal compression and tension as it bends.

This is where the silicon - the most brittle material - is usually positioned,

according to Dr Rogers.

"If you locate your circuits there, you can bend your overall system to a very

tight radius of curvature, but your circuit doesn't experience any strain," he

said.

To create the foldable chips, these circuit layers are deposited on a polymer

substrate which is bonded in turn to a temporary silicon base.

In some applications, stretchable and foldable integrated circuits may be the

only choice

Zhenqiang Ma

Following the deposition of the circuits, the silicon base is discarded to

reveal delicate slivers of circuitry held in plastic.

These are then bonded to a piece of pre-strained rubber. When the strain is

removed, the rubber snaps back into shape, causing the circuits on the surface

to wrinkle accordingly.

"This leads to the wavy geometry that allows the overall circuit system to be

stretched in any direction you want," said Dr Rogers.

The complete circuits are still relatively crude compared to top-end computer

chips but have typical "silicon wafer performance" for the size of the

component, he said.

Brain pad

Other companies and researchers are working on different approaches to flexible

electronics.

One approach is to make so-called "organic" electronics, also known as plastic

electronics.

These rugged devices are made from organic polymers and have been built into

flexible "electronic paper" displays.

However, they are relatively slow and therefore of limited use in high

performance devices.

The new work offers an alternative.

"There are many applications," said Professor Ma.

His own work has explored the possibility of using the technology in aircraft,

for example building compact antennae or creating 360-degree surveillance

applications by embedding chips across the surface of the fuselage.

"In some applications, such a form of stretchable and foldable integrated

circuits may be the only choice," he said.

Professor Rogers, working with other scientists, is concentrating on medical

applications.

One collaboration seeks to develop a smart latex glove for surgeons which would

measure vital signs, such as blood oxygen levels, during an operation.

Another aims to develop a sheet of electronics which could lie on the surface

of the brain to monitor brain activity in epileptics.

"Most of our energy is now focused on applications," said Professor Rogers.