When you take into account the frequency with which chipmanufacturers release their next-smallest transistor node chips, Gordon Moore's
law about cramming more components onto integrated circuits appears to be
slowing down. As they approached the single digit nano-scale transistor nodes,
Intel experienced a few slowdowns. In addition, shortages of virtually every
kind of component in the global supply chain are now causing manufacturers even
more delays.
However, a variety of strategies for carrying out thetypical transistor switching or routing task are already being investigated by
researchers. In essence, researchers want to control this signal routing with
nano- and sub-nanometer-scale transistor-like devices.
Organic transistors, specialized materials likeferroelectric transistors, and even quantum transistors, which would
necessitate entirely new hardware and completely alter the current electronic
landscape, have shown promising results in research. Additionally, our
sophisticated assembly teams will make it possible to incorporate these new
transistor-like devices into products on a global scale as they develop.
Researchers hope to solve some of humanity's most pressingissues through miniaturization. Longer, healthierlives and cleaner energy that can power everything from autonomous vehicles to
spacecraft and everything in between are the outcomes of brilliant new
breakthroughs from the most prestigious research institutions in the world.
However, consumers will not be able to access this research if it is not
assembled using advanced electronics.
Advanced electronics assembly makes research real byfiguring out how to make things on a large scale, cutting costs, and using a
lot of engineering knowledge. An advanced electronics assembly team can help
you seamlessly transition from prototype to production, regardless of how small
or complex the electronics are, whether you're a startup or a technology leader
in the Fortune 500.
