New thin-film semiconductor techniques invented by UW-Madison engineers promise to add sensing, computing and imaging capability to an array of materials.
According to UW-Madison, the semiconductor industry has relied on flat, two-dimensional chips upon which to grow and etch the thin films of material that become electronic circuits for computers and other electronic devices. But as thin as those chips might seem, they are quite large in comparison to the result of a new UW semiconductor fabrication process.
A team, led by Electrical and Computer Engineering Assistant Professor Zhenqiang (Jack) Ma and Materials Science and Engineering Professor Max Lagally, developed a process to remove a single-crystal film of semiconductor from the substrate on which it is built.
This thin layer can be transferred to glass, plastic or other flexible materials, opening a wide range of possibilities for flexible electronics. In addition, the semiconductor film can be flipped as it is transferred to its new substrate, making its other side available for more components. This doubles the possible number of devices that can be placed on the film. By repeating the process, layers of double-sided, thin-film semiconductors can be stacked together, creating powerful, low-power, three-dimensional electronic devices.
“It’s important to note that these are single-crystal films of strained silicon or silicon germanium,” said Ma. “Strain is introduced in the way we form the membrane. Introducing strain changes the arrangement of atoms in the crystal such that we can achieve much faster device speed while consuming less power.”
For non-computer applications, flexible electronics is beginning to have a noticeable impact. Solar cells, smart cards, radio frequency identification (RFID) tags, medical applications, and active-matrix flat panel displays could all benefit from the development. The techniques could allow flexible semiconductors to be embedded in fabric to create wearable electronics or computer monitors that roll up like a window shade.
“This is potentially a paradigm shift,” said Lagally. “The ability to create fast, low-power, multilayer electronics has many exciting applications. Silicon germanium membranes are particularly interesting. Germanium has a much higher adsorption for light than silicon. By including the germanium without destroying the quality of the material, we can achieve devices with two to three orders of magnitude more sensitivity.”
That increased sensitivity could be applied to create superior low-light cameras, or smaller cameras with greater resolution. Ma, Lagally, Materials Science and Engineering Assistant Professor Paul Evans, Physics Associate Professor Mark Eriksson, and graduate students Hao-Chih Yuan and Guogong Wang are patenting the new techniques through the Wisconsin Alumni Research Foundation.