Global PCB Connections: A Field Engineer’s Perspective on the Top 10 Trends to Watch
Target Condition: Designing vs. Inventing
Dana on Data: The Missing AI-NPI Link
Since the 1960s, computer chips have been built using a process called photolithography. But in the past five years, chip features have gotten smaller than the wavelength of light, which has required some ingenious modifications of photolithographic processes. Keeping up the rate of circuit miniaturization that we’ve come to expect — as predicted by Moore’s Law — will eventually require new manufacturing techniques.
Block copolymers, molecules that spontaneously self-assemble into useful shapes, are one promising alternative to photolithography. In a new paper in the journal Nature Communications, MIT researchers describe the first technique for stacking layers of block-copolymer wires such that the wires in one layer naturally orient themselves perpendicularly to those in the layer below.
The ability to easily produce such “mesh structures” could make self-assembly a much more practical way to manufacture memory, optical chips, and even future generations of computer processors.
“There is previous work on fabricating a mesh structure — for example our work,” says Amir Tavakkoli, a postdoc in MIT’s Research Laboratory of Electronics and one of three first authors on the new paper. “We used posts that we had fabricated by electron-beam lithography, which is time consuming. But here, we don’t use the electron-beam lithography. We use the first layer of block copolymer as a template to self-assemble another layer of block copolymer on top of it.”
Tavakkoli’s co-first-authors on the paper are Sam Nicaise, a graduate student in electrical engineering, and Karim Gadelrab, a graduate student in materials science and engineering. The senior authors are Alfredo Alexander-Katz, the Walter Henry Gale Associate Professor of Materials Science and Engineering; Caroline Ross, the Toyota Professor of Materials Science and Engineering; and Karl Berggren, a professor of electrical engineering.
Page 1 of 3
Share on:
Suggested Items
NUS Physicists Discover a Copper-free High-temperature Superconducting Oxide
03/28/2025 | PRNewswireProfessor Ariando and Dr Stephen Lin Er Chow from the National University of Singapore (NUS) Department of Physics have designed and synthesised a groundbreaking new material—a copper-free superconducting oxide—capable of superconducting at approximately 40 Kelvin (K), or about minus 233 degrees Celsius (deg C), under ambient pressure.
Indium to Showcase Proven EV Products and High-Reliability Alloys at Productronica China
03/26/2025 | Indium CorporationAs a global materials supplier and trusted partner in electric vehicle (EV) and e-Mobility manufacturing, Indium Corporation® is proud to showcase its high-reliability alloys and soldering solutions at Productronica China, March 26-28, in Shanghai, China.
Queen's University Belfast Enhances RF Research with LPKF ProtoLaser R4
03/26/2025 | LPKFThe Centre for Wireless Innovation (CWI) at Queen's University Belfast relies on the state-of-the-art LPKF ProtoLaser R4 to conduct RF research with high-precision structuring of sensitive materials.
SolderKing Enhances Brainboxes' Electronics Manufacturing with Expert Support and Advanced Materials
03/26/2025 | SolderKingIn modern electronics manufacturing, success relies on more than high-quality soldering materials. Technical knowledge and process expertise are just as crucial for achieving consistent results. SolderKing, a leading UK manufacturer, provides both, combining advanced consumables with specialist support to help manufacturers optimise their soldering processes.
Global PCB Connections: A Field Engineer’s Perspective on the Top 10 Trends to Watch
03/27/2025 | Jerome Larez -- Column: Global PCB ConnectionsAs a field application engineer for a major Chinese PCB company, I see firsthand the challenges and, more excitingly, the trends shaping our industry. Talking to engineers, designers, and procurement teams worldwide, one thing is clear: PCBs have come a long way, but we’re barely scratching the surface of what’s possible. Here are 10 trends I believe will define our industry over the next decade.