Researchers at the University of Washington, working with researchers from the ETH-Zurich, Purdue University and Virginia Commonwealth University, have achieved an optical communications breakthrough that could revolutionize information technology.
They created a tiny device, smaller than a human hair, that translates electrical bits (0s and 1s of the digital language) into light, or photonic bits, at speeds 10s of times faster than current technologies.
These new electro-optic devices approach the size of current electronic circuit elements and are important for integrating photonics and electronics on a single chip. The new technology also involves utilization of a particle, a plasmon polariton, that has properties intermediate between electrons and photons. This hybrid particle technology is referred to as plasmonics.
The findings were published today in the journal Nature.
To increase the information-handling capacity of computing, telecommunications, sensing and control technologies, data needs to be communicated with high bandwidth over vast distances without signals (information) degrading, or consuming too much energy and generating too much heat. That’s where the new technology described in the Nature article fits in. Called an electro-optic modulator, the device converts electrical signals into optical ones capable at traveling either over fiberglass optic cabling or wirelessly through space via satellite and cell towers. This must be accomplished with excellent energy efficiency using extremely small devices capable of processing massive amounts of data.
This latest advance follows on a breakthrough in 2000 when Larry Dalton and a team of UW and University of Southern California researchers first introduced newly designed electro-optical polymers or plastics, which were integrated into centimeter-long devices that could be operated with less than a volt and with bandwidths exceeding 100 gigahertz. Unfortunately, these devices were much larger than electronic data-generating elements and were not suited for integration of electronics and photonics elements on a single chip.
However, transitioning to plasmonics, this footprint issue has now been solved. And it all started when an international team of scientists and engineers set out to improve the device by integrating better organic electro-optic materials with plasmonics. Plasmons are created when light impinges onto a metallic surface, such as gold. Photons then pass on part of their energy to the electrons on the metallic surface such that the electrons oscillate. These new photon-electron oscillations are called plasmon polaritons. Working with plasmon polaritons permits dramatic reduction in the size of optical circuitry and bandwidth operation many times that of photonics. Compared to the 2000 discovery, the bandwidth of the devices increased by almost a factor of 10 while reducing the energy requirements by almost 1,000 and this translates into a reduction in heating.
The Achilles’ heel of plasmonics, however, is referred to as optical loss. While signal degradation with distance of transmission is not as bad as with electronics, signal degradation with plasmonics is much worse than with photonics.
“The ETH and Purdue researchers conceived of an elegant device architecture that addresses the problem of plasmonic loss and achieves loss comparable to that of all-photonic modulators by using a combination of plasmonics and photonics,” Dalton said.
He called the device an elegant integration of electronics, photonics and plasmonics, using an organic electro-optic material that permits integration of all of the signal processing options.
“This is a doubly significant advance in plasmonics and organic electroactive materials, made possible through creative iteration between materials prediction, design, synthesis, and property optimization,” said Linda S. Sapochak, division director for materials research at the National Science Foundation, which helped fund the research.
The integration of electronics and photonics on chips has been recognized for more than a decade as a critical next step in the evolution of information technology. Information technology is the science of how we sense our world and both process and communicate that information.
The applications of the new device can be divided into two categories based on the wavelength of light used: Fiber optics telecommunications and optical interconnects in computing utilize light (photons) at optical frequencies (infrared light), while applications such as radar and wireless telecommunications use electromagnetic radiation in the radiofrequency and microwave (long wavelength light) regions.
In the telecommunications and computing space, electro-optics takes information generated in an electronic device (for example, a computer processor) and transform it into light signals that travel over a fiber optic cable or via a wireless transmission to another electronic device.
Electro-optics also is critical to many other applications such as radar and GPS. It represents critical sensor technology, including applications such as embedded network sensing. For example, electro-optics is critical to many components of an autonomous vehicle and for monitoring infrastructure elements such as buildings and bridges. The device is relevant to both digital and analog information processing.
Co-authors include Daniel Chelladurai, Yuriy Fedoryshyn, Arne Josten, Benedikt Baeuerle, Wolfgang Heni, Tatsuhiko Watanabe, Tong Cui, Bojun Cheng and Juerg Leuthold of ETH Zurich Institute of Electromagnetic Fields; Delwin L. Elder of the UW Department of Chemistry; Soham Saha, Alexandra Boltasseva and Vladimir Shalaev, Purdue University and Brick Nanotechnology Center; and Nathaniel Kinsey, Virginia Commonwealth University.
Funding for this project is from EU Project PLASMOFAB (688166), the ERC grant PLASILOR (640478), the National Science Foundation (DMR-1303080) and the Air Force Office of Scientific Research grants (FA9550-15-1-0319 and FA9550-14-1-0138). Co-author Kinsey acknowledges support from the Virginia Microelectronics Consortium and the Virginia Commonwealth University Presidential Research Quest Fund.