-
- News
- Books
Featured Books
- design007 Magazine
Latest Issues
Current IssueRules of Thumb
This month, we delve into rules of thumb—which ones work, which ones should be avoided. Rules of thumb are everywhere, but there may be hundreds of rules of thumb for PCB design. How do we separate the wheat from the chaff, so to speak?
Partial HDI
Our expert contributors provide a complete, detailed view of partial HDI this month. Most experienced PCB designers can start using this approach right away, but you need to know these tips, tricks and techniques first.
Silicon to Systems: From Soup to Nuts
This month, we asked our expert contributors to weigh in on silicon to systems—what it means to PCB designers and design engineers, EDA companies, and the rest of the PCB supply chain... from soup to nuts.
- Articles
- Columns
Search Console
- Links
- Media kit
||| MENU - design007 Magazine
Smarter Self-assembly Opens New Pathways for Nanotechnology
August 10, 2016 | Brookhaven National LaboratoryEstimated reading time: 3 minutes
To continue advancing, next-generation electronic devices must fully exploit the nanoscale, where materials span just billionths of a meter. But balancing complexity, precision, and manufacturing scalability on such fantastically small scales is inevitably difficult. Fortunately, some nanomaterials can be coaxed into snapping themselves into desired formations-a process called self-assembly.
Scientists at the U.S. Department of Energy's (DOE) Brookhaven National Laboratory have just developed a way to direct the self-assembly of multiple molecular patterns within a single material, producing new nanoscale architectures. The results were published in the journal Nature Communications.
"This is a significant conceptual leap in self-assembly," said Brookhaven Lab physicist Aaron Stein, lead author on the study. "In the past, we were limited to a single emergent pattern, but this technique breaks that barrier with relative ease. This is significant for basic research, certainly, but it could also change the way we design and manufacture electronics."
Microchips, for example, use meticulously patterned templates to produce the nanoscale structures that process and store information. Through self-assembly, however, these structures can spontaneously form without that exhaustive preliminary patterning. And now, self-assembly can generate multiple distinct patterns-greatly increasing the complexity of nanostructures that can be formed in a single step.
"This technique fits quite easily into existing microchip fabrication workflows," said study coauthor Kevin Yager, also a Brookhaven physicist. "It's exciting to make a fundamental discovery that could one day find its way into our computers."
The experimental work was conducted entirely at Brookhaven Lab's Center for Functional Nanomaterials (CFN), a DOE Office of Science User Facility, leveraging in-house expertise and instrumentation.
Cooking up organized complexity
The collaboration used block copolymers-chains of two distinct molecules linked together-because of their intrinsic ability to self-assemble.
"As powerful as self-assembly is, we suspected that guiding the process would enhance it to create truly 'responsive' self-assembly," said study coauthor Greg Doerk of Brookhaven. "That's exactly where we pushed it."
To guide self-assembly, scientists create precise but simple substrate templates. Using a method called electron beam lithography-Stein's specialty-they etch patterns thousands of times thinner than a human hair on the template surface. They then add a solution containing a set of block copolymers onto the template, spin the substrate to create a thin coating, and "bake" it all in an oven to kick the molecules into formation. Thermal energy drives interaction between the block copolymers and the template, setting the final configuration-in this instance, parallel lines or dots in a grid.
"In conventional self-assembly, the final nanostructures follow the template's guiding lines, but are of a single pattern type," Stein said. "But that all just changed."
Lines and dots, living together
The collaboration had previously discovered that mixing together different block copolymers allowed multiple, co-existing line and dot nanostructures to form.
"We had discovered an exciting phenomenon, but couldn't select which morphology would emerge," Yager said. But then the team found that tweaking the substrate changed the structures that emerged. By simply adjusting the spacing and thickness of the lithographic line patterns-easy to fabricate using modern tools-the self-assembling blocks can be locally converted into ultra-thin lines, or high-density arrays of nano-dots.
"We realized that combining our self-assembling materials with nanofabricated guides gave us that elusive control. And, of course, these new geometries are achieved on an incredibly small scale," said Yager.
"In essence," said Stein, "we've created 'smart' templates for nanomaterial self-assembly. How far we can push the technique remains to be seen, but it opens some very promising pathways."
Gwen Wright, another CFN coauthor, added, "Many nano-fabrication labs should be able to do this tomorrow with their in-house tools-the trick was discovering it was even possible."
The scientists plan to increase the sophistication of the process, using more complex materials in order to move toward more device-like architectures.
"The ongoing and open collaboration within the CFN made this possible," said Charles Black, director of the CFN. "We had experts in self-assembly, electron beam lithography, and even electron microscopy to characterize the materials, all under one roof, all pushing the limits of nanoscience."
Suggested Items
Winners of IPC Hand Soldering World Championship at electronica 2024 Announced
11/21/2024 | IPCIPC hosted its Hand Soldering World Championship in Munich, Germany, at electronica on 14-15 November 2024, welcoming 14 competitors from 13 companies and 12 countries worldwide. Skilled contestants competed to build an electronics assembly in accordance with IPC-A-610 Class 3 criteria, and were judged on the functionality of the assembly, compliance with the assembly process and overall product quality. The contestants were allowed a maximum of 60 minutes to complete the assembly.
PCB Carolina’s Formula: Industry Experts and Catered Food
11/18/2024 | Andy Shaughnessy, Design007 MagazinePCB Carolina organizers at the Better Boards design bureau seem to have found the perfect formula: Industry experts plus catered food equals a constantly expanding show. This one-day tabletop show has been growing for two decades, and that trendline continued with this year’s event on November 13.
Virginia is for (PCB) Lovers: Weidmuller USA Celebrating 50 Years in Virginia
11/18/2024 | Linda Stepanich, IPCThe Weidmuller Group, a provider of Smart Industrial Connectivity products and solutions, is a family-owned company founded in 1850 in Germany. It currently operates sites in more than 80 countries. Weidmuller USA, based in Richmond, Virginia, and celebrating 50 years in 2025, plans to open an engineering and production facility this fall, bringing more jobs to the region.
Data-driven Precision in PCBA Manufacturing
11/13/2024 | Julie Cliche-Dubois, CogiscanThe intricacies involved in electronics manufacturing require more than just expensive equipment and skilled technicians; they necessitate an accurate understanding of the entire production flow, informed and driven by access and visibility to reliable data.
Discover the Future of PCB and PCBA at the International Electronics Circuit Exhibition
11/01/2024 | HKPCAThe International Electronics Circuit Exhibition (Shenzhen) (HKPCA Show) is one of the largest and most influential trade shows in the PCB and electronic assembly industry. Having already been successfully held 21 times, the Show takes place every December.