Tuesday November 2, 2004 JbE EAihtriuta aiu SCIENCE 5 news@michigandaily.com BY ADRIAN CHEN DAILY STAFF REPORTER Turing the Solid State Electronics Laboratory is like being in a subma- rine - pipes and tubes line narrow, dimly lit halls, and the monotony of cinder- block walls is broken occasionally by con- soles bristling with meters and valves, strobe lights ready to flash out warnings should something go wrong. The hallways pass large racks of buzzing metal and wire and a constant hum resonates from the floor. Sandrine Martin pauses while navigating the SSEL's corridors to point to a room emitting a pale yellow glow. "That's our most expensive piece of equipment," says Martin, an adjunct electrical engineering and computer science pro- fessor. Inside is a large rectangular box that looks like a stainless steel refrigerator on its side, only with more doors. It's called an electron-beam lithographer, and it costs $1 million. The point of it all: to produce as little as possible. That's the mantra of the fields of micro- and nanotechnology, which are at the center of research in the North Campus lab. Micro- and nanotechnology deal with the manipulation of substances at extremely small scales to make tiny mechanisms and electronics. The difference between micro- and nanotechnology lies solely in scale: Nan- otechnology is more minuscule extension of microtechnology. Less is more for the scientists who continually push for smaller structures and finer detail. And today, "less" is tinier than ever before: "micro" refers to the micron, a unit of length that is a mil- lionth of a meter (a human hair is 15 microns in diameter). A nanometer is a thousandth of a micron or one billionth of a meter. "When you go down to these levels, you are at the same scales as the distance between two atoms or a molecule," Martin said. But Martin and her colleagues' obsession with ever shrinking-technology begs the question: What's the point? Khalil Najafi, an electrical engineering and computer science professor and director of the SSEL, smiled when asked the question. "Well, that will take a long time to answer." very aspect of modern life and many scientific fields, such as biotechnol- ogy, could potentially be impacted by nanotechnology, Najafi said. "Because it deals with the smallest elements of many objects, nanotechnology will have a profound impact on" everything from the The point of materials we use in our daily lives, such produce as lit as coatings to protect fabric, to many new drugs being developed that require (nanotechnol- ogy) to amplify their effectiveness and reduce their side effects," he said. Using nanotechnolo- gy, researchers can gain insight into the chemical makeup of these fabrics and drugs and manipu- RYAN WEINER/Daily Nanotechniogy researchers work at the electri- cal engineering and computer science lab on North Campus. Because of high maintenance costs, the lab is one of the few of its kind in the country and shares its facili- ties with outside, non-University parties regularly. The lab is also now part of a national network of nanotechnol- ogy labs that encourage inte- gration of the field into other, more unexpected disciplines. JDUSTRY A s much as it has benefited the University community, nanotechnology has been good for Ann Arbor's economy as well. An entire industry of micro- and nanotechnology startups has sprung up around the area thanks to the facilities at the SSEL, Terry said. "Without these facilities, those companies wouldn't be here," he said. Nanotechnology has the potential to benefit the state of Michigan as well, said John Bedz, direc- tor of the Michigan Small Tech Association - an organization dedicated to promoting micro- and nanotechnology investment in the state. "Material sciences have always been par- ticularly important to the state's economy, and the ability to work at this scale will make nanotechnology an important part of the future," he said. "Nano-enhanced appli- cations will find their way into everything. Anything that's made of something can ben- efit from nanotechnology." Bedz cited Telurex, a Michigan company, as an instance of nanotechnology's contribution THE SKINNY ON THE BOOMING NANOTECH IN late them to increase their efficiency. This same technology could offer doctors new ways to monitor their patients' vital signs through tiny implanted machines, Martin said. "These devices can go through the skin or use the blood system as channels and circulate in the body," she said. Once there, they can be used to check up on a patient or administer specifi- cally targeted drugs. Nanotechnology could also aid environ- mental scientists in developing strategies to combat pollution. "Pollution is caused - in one form or another - by nano-sized par- ticles, and understanding how these particles are generated and interact with one another and the atmosphere will help us to either prevent or mitigate problems that come up," Najafi said. it all: to ttle as possible But nanotechnol- ogy isn't just part of a distant future where tiny robots scrub the air. In fact, nanotech- nology is already ubiquitous in today's world. You just might not be able to see it - and that's the point. Advances in micro- and nanotechnology, for instance, are responsible for the small-and-get- ting-smaller size of many electronics. "Already, many electronic products from computers to ... music players and cameras incorporate what we call 'nan- otechnology-enabled' devic- es," Najafi said. "Computer chips are made of transistors that are about 100 nanometers large and can therefore con- tain hundreds of millions of transistors in an area smaller than a postage stamp." anotechnology has also been put to prac- tical use outside the electronics industry; compa- nies have used nanotechnol- ogy to develop stain-resistant pants and flexible tennis rac- quets with the strength of steel. These materials were made using many techniques perfected in nanotechnology labs like the SSEL. And as nano- and micro- technology advance, the fields to which they can be applied continue to expand. Micro-electro-mechani- cal systems is one area of research being explored at the SSEL that could have a wide-reaching impact. MES aims to build complex gear systems, motors and valves at the micron level. These components can then be assembled to make fully functioning microsystems. Najafi is working on integrating MES with wireless technology to develop tiny sensors with a broad range of applications. These sensors could be applied to fields not normally associated with microtech- nology, such as environmental science and homeland security. For example, Najafi and his colleagues are attempting to shrink a collection of large lab instruments into a "wristwatch laboratory" that could monitor airborne biological threats or pollution - all powered by a watch battery. This portable lab could offer near-instantaneous results in a convenient package. As the field of microtechnology expands, nan- otechnology is sure to follow, Martin said. The broadening of the nanotechnology field should offer benefits to many more scientists, but it introduces new challenges for researchers and labs like the SSEL, Martin said. More scientists interested in 'nanotechnology leads to more scientists coming to labs like the SSEL - scientists who may or may not be famil- iar with the delicate machinery used and complex protocols followed at the lab. And protocols and delicacy are of the utmost importance when working at the nanometer level. As the scale of this work shrinks, the number of precautions taken to ensure a clean working environment and functioning equipment grows .in proportion. "At these small scales, a thing of dust is huge," Martin said. "This is a problem when you're doing micro- and-nanoelectronics: A dirt particle on a circuit can ruin it." So the SSEL keeps its equipment in sterile "clean rooms" bathed in yellow light to protect it from damaging ultraviolet rays. Research- ers are swaddled in blue coveralls and surgical masks so that only their eyes show - and those are encased in safety goggles to contain errant eyelashes. Ventilators roar as they furiously circulate air to prevent dust buildup, changing the air in the room as many as 500 times an hour. A normal office building usually has one air change per hour. But despite these precautions, problems with the equipment abound. "It's really what you could call bad equip- ment," Martin said. "It's very expensive to buy, expensive to install, expensive to maintain, and it breaks down often." Even a 75 percent rate of operation is considered a boon, she said. The difficulty and cost of maintaining the equipment needed for nanotechnology research means that only a select number of universities and companies can have extensive facilities like the SSEL. As a result, scientists looking to work on nanotechnology often have to travel a substan- tial distance to such labs. The lab has hosted people from all over the United States, and local companies regularly use the facility, Martin said. And this is where the inexperience and lack of knowledge is most often felt. "We had people coming.in who weren't famil- iar with nanotechnology and didn't know how to use the equipment," Martin said. When searching for help with the facilities, it was often hit-or-miss, with no structured training program in place. But starting this year, the SSEL is a mem- ber of the National Nanotechnology Infra- structure Network, and Martin thinks things are changing for the better. NNIN is a nationwide network of 13 nanotechnology facili- ties, sponsored by the National Science Founda- tion, charged with increasing accessibility to the field through greater training and outreach. Earlier this year, the SSEL was named as part of the network following a nationwide competi- tion. As an NNIN facility, the SSEL receives $1.2 million annually, which is used primarily to hire and pay new staff. The staff was hired partially to accommodate a potential increase in new users, as one of the goals of NNIN is to get more people outside of the field involved with nanotechnology research. Najafi, who along with his colleague te EECS Prof. Fred Terry At these sn is responsible for bring- thif du ing the NNIN to Michi- gan, is excited about the ability to reach out to other fields that NNIN Electric provides. "More and more peo- Computer Scienc hall scales, a st is huge." - Sandrine Martin cal Engineering and e Adjunct Professor to the state's econo- my. Based in Traverse City, the company has developed cup holders that can change tem- perature to keep hot drinks warm or cold drinks cool based on nanotechnology. Bedz also said the auto industry, which ple are saying, 'If only I could do that (using nanotechnology),' " he said. "Now we can have professional staff to help them get in the lab and do it." Martin, who is the new NNIN technical manager, said the SSEL's status as a hub for nanotechnology research should help every- one involved with nanotechnology at the University. The new staff and training procedures should especially help external users who are relatively unfamiliar with nanotechnology, Martin said. "Now, instead of having to search for a lot of answers ... (outside users) are a little more guid- ed." Martin said, "The training is anew thing; it's more formalized. A lot of people are getting a lot of help so things should be easier." Najafi said the exchange of ideas that will accompany an influx of outside researchers should be beneficial for all involved. "We can learn from them, and they can learn from us," he said. The coordination between departments within the University as more faculty take advantage of nano- technology resources should also help all involved advance their respective research, Najafi added. This is already happening to an extent. Najafi referred to an instance when a geol- ogy professor with no nanotechnology experience was able to take advantage of the SSEL facilities to create an artificial rock for a project. is always looking for stronger, lighter materials, could look to nanotechnology. Research at the University could also have a direct impact on fields such as the computer industry. Linjie Guo, an EECS professor, is developing a procedure called nanoimprinting that could change the way microprocessors are made. Currently, microchips are made using a technique called electron-beam lithography to "etch" the tiny circuits and patterns needed into a chip. This is becoming more and more expensive as processors get more complex. Guo and his colleagues have developed what they said is a more efficient process wherein a design can be "stamped" onto a surface using a template. The computer industry has taken notice. "This technique is becoming quite success- ful," he said. "The semiconductor industry has officially put this on their road map for their next generations of chips." Nanotechnology may seem like a lucrative field, but it takes a lot of upfront capital to get things started: The hourly rate for access at the SSEL can be upwards of $70 an hour for external, non-University users - materials not included. But if you have the cash and an affinity for blue coveralls, the world of nanotechnology awaits. And the newly established NNIN should make things that much easier. Just don't drop whatever it is you're working on-chances are you'll never find it. 'U' researchers look into mystery of late-onset autism By Kingson Man Daily Staff Reporter Just as he turns 19 months old, a child suddenly loses his interest in playing peek- a-boo. Skills that he was just learning to acquire - making eye contact, using ges- tures and forming meaningful words - are mysteriously lost. The child, who seemed to be developing normally during his first year and a half. is now displaying signs of then they begin to show a drastic decline in social and cognitive ability. Recent findings by University researchers tracks the path of regression in a subset of children with autism indicating that children do not suddenly become autistic after devel- oping normally for a year and a half The studies will be published in upcoming issues of Developmental Psychology and the Jour- nal of Autism and Developmental Disorders. In the studies gathered information from After the onset of regression, however, these children are impaired to an equal or greater degree as autistic children with- out regression. This effect, so far, has been observed for years afterward. For this subset of autistics, those with regression start ahead of afflicted newborns but end behind in measures of social and psychological impairment. Jennifer Richler, one of the lead research- ers of the study and a psychology graduate found no evidence for such a link," Richler. said There was also no link between the vac- cine and the regressive form of autism. However, the study found other links. Interviews with parents of autistic children showed that there was a connection between the disorder and a family history of autoim- mune disease. While the authors of the papers acknowl- edged the help of parents of autistic children t'~ '~ '4 '-~ ~ ~c.x<.x*x*x..,X.'O~. ~