Ultrathin, flexible computer circuits have been an engineering goal for years, but technical hurdles have prevented the degree of miniaturization necessary to achieve high performance. Now, researchers at Stanford University have invented a manufacturing technique that yields flexible, atomically thin transistors less than 100 nanometers in length — several times smaller than previously possible.
With the advance, said the researchers, so-called “flextronics” move closer to reality. Flexible electronics promise bendable, shapeable, yet energy-efficient computer circuits that can be worn on, or implanted in, the human body to perform myriad health-related tasks. What’s more, the coming “internet of things,” in which almost every device in our lives is integrated and interconnected, should similarly benefit from flextronics.
Among suitable materials for flexible electronics, two-dimensional (2D) semiconductors have shown promise because of their excellent mechanical and electrical properties, even at the nanoscale, making them better candidates than conventional silicon or organic materials.
The engineering challenge to date has been that forming these almost impossibly thin devices requires a process that is far too heat-intensive for flexible plastic substrates. These materials would simply melt and decompose in the production process.
The solution according to the researchers, is to do it in steps, starting with a base substrate that is anything but flexible. They formed an atomically thin film of the 2D semiconductor molybdenum disulfide (MoS2) overlaid with small nano-patterned gold electrodes atop a solid slab of silicon coated with glass. Because this step is performed on the conventional silicon substrate, the nanoscale transistor dimensions can be patterned with existing advanced patterning techniques, achieving a resolution otherwise impossible on flexible plastic substrates.
This layering technique, known as chemical vapor deposition (CVD), grows a film of MoS2 one layer of atoms at a time. The resulting film is just three atoms thick but requires temperatures reaching 850°C (over 1500°F) to work. By comparison, the flexible substrate — made of polyimide, a thin plastic — would have lost its shape somewhere around 360°C (680°F), and completely decomposed at higher temperatures.
By first patterning and forming these critical parts on rigid silicon and allowing them to cool, the Stanford researchers can apply the flexible material without damage. With a simple bath in deionized water, the entire device stack peels back, now fully transferred to the flexible polyimide.
After a few additional fabrication steps, the results are flexible transistors capable of several times better performance than any produced before with atomically thin semiconductors. The researchers said that while entire circuits could be built and then transferred to the flexible material, certain complications with subsequent layers make these additional steps easier after transfer.
“In the end, the entire structure is just 5 microns thick, including the flexible polyimide,” said Professor Eric Pop. “That’s about ten times thinner than a human hair.”
While the technical achievement in producing nanoscale transistors on a flexible material is notable in its own right, the researchers also described their devices as “high performance,” which in this context means that they are able to handle high electrical currents while operating at low voltage, as required for low power consumption.
“This downscaling has several benefits,” said Dr. Daus. “You can fit more transistors in a given footprint, of course, but you can also have higher currents at lower voltage — high speed with less power consumption.”
Meanwhile, the gold metal contacts dissipate and spread the heat generated by the transistors while in use — heat that might otherwise jeopardize the flexible polyimide.
With a prototype and patent application complete, Daus and Pop have moved on to their next challenges of refining the devices. They have built similar transistors using two other atomically thin semiconductors (MoSe2 and WSe2) to demonstrate the broad applicability of the technique.
Meanwhile, Daus said that he is looking into integrating radio circuitry with the devices, which will allow future variations to communicate wirelessly with the outside world — another large leap toward viability for flextronics, particularly those implanted in the human body or integrated deep within other devices connected to the internet of things.
“This is more than a promising production technique. We’ve achieved flexibility, density, high performance and low power — all at the same time,” Pop said. “This work will hopefully move the technology forward on several levels.”