Penn Engineering Research Gives Optical Switches the ‘Contrast’ of Electronic Transistors

Reading time ( words)

Current computer systems represent bits of information — the 1’s and 0’s of binary code — with electricity. Circuit elements, such as transistors, operate on these electric signals, producing outputs that are dependent on their inputs.

​​​​​​​As fast and powerful as computers have become, Ritesh Agarwal, professor in the Department of Materials Science and Engineering in the University of Pennsylvania’s School of Engineering and Applied Science, knows they could be more powerful. The field of photonic computing aims to achieve that goal by using light as the medium.

agarwal.JPGAgarwal’s research on photonic computing has been focused on finding the right combination and physical configuration of materials that can amplify and mix light waves in ways that are analogous to electronic computer components.

​​​​​​​In a paper published in Nature Communications, he and his colleagues have taken an important step: precisely controlling the mixing of optical signals via tailored electric fields, and obtaining outputs with a near perfect contrast and extremely large on/off ratios. Those properties are key to the creation of a working optical transistor.

“Currently, to compute ‘5+7,’ we need to send an electrical signal for ‘5’ and an electrical signal for ‘7,’ and the transistor does the mixing to produce an electrical signal for ‘12,’” Agarwal said. “One of the hurdles in doing this with light is that materials that are able to mix optical signals also tend to have very strong background signals as well. That background signal would drastically reduce the contrast and on/off ratios leading to errors in the output.”

With background signals washing out the intended output, necessarily computational qualities for optical transistors, such as their on/off ratio, modulation strength and signal mixing contrast have all been extremely poor. Electric transistors have high standards for these qualities to prevent errors.

The search for materials that can serve in optical transistors is complicated by additional property requirements. Only “nonlinear” materials are capable of this kind of optical signal mixing.


Figure A shows a diagram of the the Agarwal research group’s “nanobelt.”

To address this issue, Agarwal’s research group started by finding a system which has no background signal to start: a nanoscale “belt” made out of cadmium sulfide. Then, by applying an electrical field across the nanobelt, Agarwal and his colleagues were able to introduce optical nonlinearities to the system that enable a signal mixing output that was otherwise zero.

“Our system turns on from zero to extremely large values, and hence has perfect contrast, as well as large modulation and on/off ratios,” Agarwal said. “Therefore, for the first time, we have an optical device with output that truly resembles an electronic transistor.”

With one of the key components coming into focus, the next steps toward a photonic computer will involve integrating them with optical interconnects, modulators, and detectors in order to demonstrate actual computation.


Suggested Items

Beyond Scaling: An Electronics Resurgence Initiative

06/05/2017 | DARPA
The Department of Defense’s proposed FY 2018 budget includes a $75 million allocation for DARPA in support of a new, public-private “electronics resurgence” initiative. The initiative seeks to undergird a new era of electronics in which advances in performance will be catalyzed not just by continued component miniaturization but also by radically new microsystem materials, designs, and architectures.

DARPA Researchers Develop Novel Method for Room-Temperature Atomic Layer Deposition

09/01/2016 | DARPA
DARPA-supported researchers have developed a new approach for synthesizing ultrathin materials at room temperature—a breakthrough over industrial approaches that have demanded temperatures of 800 degrees Celsius or more. T

Finessing Miniaturized Magnetics into the Microelectronics Mix

06/20/2016 | DARPA
A newly-announced DARPA program is betting that unprecedented on-chip integration of workhorse electronic components, such as transistors and capacitors, with less-familiar magnetic components with names like circulators and isolators, will open an expansive pathway to more capable electromagnetic systems.

Copyright © 2018 I-Connect007. All rights reserved.