The Government Circuit: News on Defense Electronics, Europe, and Sustainability
American Made Advocacy: Taking the Fight to Capitol Hill
Defense Speak Interpreted: SWaPing Nanosatellites for Defense Systems
Self-Stacking Nanogrids
January 22, 2016 | MITEstimated reading time: 4 minutes
Polymers are long molecules made from basic molecular units strung into chains. Plastics are polymers, and so are biological molecules like DNA and proteins. A copolymer is a polymer made by joining two different polymers.
In a block copolymer, the constituent polymers are chosen so that they’re chemically incompatible with each other. It’s their attempts to push away from each other — both within a single polymer chain and within a polymer film — that causes them to self-organize.
In the MIT researchers’ case, one of the constituent polymers is carbon-based, the other silicon-based. In their efforts to escape the carbon-based polymer, the silicon-based polymers fold in on themselves, forming cylinders with loops of silicon-based polymer on the inside and the other polymer bristling on the outside. When the cylinders are exposed to an oxygen plasma, the carbon-based polymer burns away and the silicon oxidizes, leaving glass-like cylinders attached to a base.
To assemble a second layer of cylinders, the researchers simply repeat the process, albeit using copolymers with slightly different chain lengths. The cylinders in the new layer naturally orient themselves perpendicularly to those in the first.
Chemically treating the surface on which the first group of cylinders are formed will cause them to line up in parallel rows. In that case, the second layer of cylinders will also form parallel rows, perpendicular to those in the first.
But if the cylinders in the bottom layer are allowed to form haphazardly, snaking out into elaborate, looping patterns, the cylinders in the second layer will maintain their relative orientation, creating their own elaborate, but perpendicular, patterns.
The orderly mesh structure is the one that has the most obvious applications, but the disorderly one is perhaps the more impressive technical feat. “That’s the one the materials scientists are excited about,” Nicaise says.
Page 2 of 3
Share on:
Suggested Items
AIM to Present on Micro/MiniLED Applications at Hangjia Talk in Shenzhen, China
11/11/2024 | AIM SolderAIM Solder, a leading global manufacturer of solder assembly materials for the electronics industry, is pleased to announce its participation in the upcoming Hangjia annual industry event focused on the future of the LED display sector.
Henkel, Covestro and Quad Industries Collaborate for Advanced Medical Wearables Based on Printed Electronics
11/11/2024 | WEBWIREHenkel, Covestro and Quad Industries today have announced a partnership in the field of printed electronics. By joining forces and combining their different areas of expertise the companies aim to accelerate customer developments for advanced medical wearables and to further drive the adoption of innovative printed electronics solutions especially for stretchable materials in healthcare applications.
Boston Materials Announces $13.5M in New Funding for Manufacturing Expansion and Establishing Supply Chain Partnerships
11/08/2024 | PRNewswireBOSTON MATERIALS, INC., a manufacturer of advanced materials key to the next generation of semiconductors and aircraft platforms, today announced $13.5 million in new funding.
BWXT to Acquire L3Harris’ A.O.T. Business to Expand Special Materials Portfolio
11/05/2024 | L3Harris TechnologiesBWX Technologies, Inc. and L3Harris Technologies, Inc. announced the signing of a purchase agreement for BWXT to acquire L3Harris’ Aerojet Ordnance Tennessee, Inc. (A.O.T.) business for approximately $100 million.
Solid-State Batteries Enter Pilot Production, Costs Expected to Drop to CNY 0.6–0.7/Wh by 2035
11/01/2024 | TrendForceThe global pursuit and anticipation of applications for solid-state batteries (SSBs) have accelerated the commercialization process of this technology.