On Feb. 12, Daniel Blumenthal, professor in the Department of Electrical and Computer Engineering (ECE) at UC Santa Barbara, was named the recipient of the 2020 C.E.K. Mees Medal, given by The Optical Society of America (OSA). Blumenthal was honored for his innovations in ultra-low-loss photonic integrated circuits and their applications. He will receive the medal on March 10 at the annual Optical Fiber Communications (OFC) Conference in San Diego.”

Blumenthal, who leads ECE’s Optical Communications and Photonic Integration (OCPI) Group and UCSB’s Terabit Optical Ethernet Center, was described by OSA President Stephen D. Fantone, founder and president of the Optikos Corporation, as “an excellent choice for the C.E.K. Mees Medal. He is an innovator who continues to push boundaries in the use of electronic and photonic materials.”

 “This is a huge honor, not just for me but for my lab group, UCSB and the CoE, and our collaborators and colleagues,” said Blumenthal, who received the news on his birthday. “Charles Townes, who invented the laser, was a recipient.”

“We at the College of Engineering offer sincere congratulations to Dan Blumenthal upon receiving this extremely prestigious award,” said Rod Alferness, dean of the UCSB College of Engineering. “The C.E.K. Mees Medal recognizes a record of optics research that is marked not only by pioneering innovation, but also by having widespread impact in diverse areas. We are deeply proud of Professor Blumenthal for his continuing contributions, and are delighted for him to receive this most-deserved recognition.”

Blumenthal’s research is focused in the areas of optical communications and optical packet switching, integrated ultra-narrow-linewidth (sub-Hz) Brillouin lasers, optical gyroscopes, highly integrated, ultra-low-loss indium photonic integrated circuits, integrated atom cooling, atomic clock photonics, nano-photonics, and microwave photonics. His UCSB lab develops new devices and system hardware to solve complex communications, transmission, switching, and signal-processing problems that are beyond the reach of current technologies. He and his colleagues have a particular focus on integrating new bench-scale functions on small chips, called photonic circuits, which are then used to build networks in ways that save energy and increase the scale of connectivity and bandwidth of data centers and the internet. 

The group’s work in developing lasers characterized by having spectrally pure, ultra-stable light sources and ultra-low wave-guide losses is finding increasingly widespread application.

“The technology is becoming pervasive, which is validation of what we’ve thought for a long time and what has been one of my passions,” Blumenthal says, “that being able to put ultra-low-loss and ultra-narrow-linewidth lasers in photonic circuits on chips was the future for a wide variety of applications across a broad range of disciplines.”

Recently, much of Blumenthal’s photonics research has been in the area of what he refers to as “beyond silicon.” For that, he says, “We work in ultra-low-loss, wide-band-gap materials — including silicon nitride, tantalum pentoxide, and aluminum oxide. We use these materials to fabricate lasers, waveguides, and other photonic circuit components. Now, we are working to impart actuation to them, that is, being able to modulate the phase or the amplitude. We’re making building blocks that people could use to make a table-top atomic clock or optical tweezers, taking all those pieces, the nuts and bolts that people put out on tables with racks full of systems and moving those functions onto the chip.”

In addition to his research in energy-efficient photonics for communications, Blumenthal has served as the principal investigator for large-scale research programs, including the DARPA/MTO-funded CSWDM, Label-Switched Optical Router (LASOR), and iPhod projects. He also has served on the board of directors for National LambdaRail and on the Internet2 Architecture Advisory Council. He has been a guest and associate editor for multiple IEEE special issues and an organizer and technical program committee member for multiple international world-renowned conferences, including the Conference on Optical Fiber Communications.

Blumenthal holds three degrees in electrical engineering: a Bachelor of Science from the University of Rochester, a Master of Science from Columbia, and a doctorate from the University of Colorado, Boulder. He was named a fellow of the National Academy of Inventors (NAI) in 2017 and is a fellow of both the IEEE and the Optical Society. He received a Presidential Early Career Award for Scientists and Engineers from the White House in 1999, a National Science Foundation Young Investigator Award in 1994 and an Office of Naval Research Young Investigator Program Award in 1997. Blumenthal has authored or co-authored more than 460 papers, holds 22 patents, and is co-author of Tunable Laser Diodes and Related Optical Sources (New York: IEEE–Wiley, 2005).

The Mees Medal recognizes an original use of optics across multiple fields and honors the memory of Mees, who contributed preeminently to the development of scientific photography, and was a charter member of OSA. The British-born Mees co-developed the first panchromatic photographic plates and was the founder and first director of the Kodak Research Laboratories in Rochester, New Work.