CCNY researchers use structured light on a chip in another photonics breakthrough

In everyday life we experience light in one of its simplest forms – optical rays or beams. However, light can exist in much more exotic forms. Thus, even beams can be shaped to take the form of spirals; so-called vortex beams, endowed with unusual properties. Such beams can make dust particles to spin, just like they indeed move along some intangible spirals.  

Light modes with such added structure are called “structured,” and even more exotic forms of structured light can be attained in artificial optical materials – metamaterials, where multiple light waves come together and combine to create the most complex forms of light. 

In their two recent works, published back-to-back in the top journals “Science Advances,” and “Nature Nanotechnology,” City College of New York  researchers from Alexander Khanikaev’s group have created structured light on a silicon chip, and used this added structure to attain new functionalities and control not available before. 

To this aim, two-dimensional optical metamaterials, referred to as metasurfaces, and hosting a special kind of structured light spinning around just like vortex beams were created. By experiments carried out in  Khanikaev’s laboratory at The City College, researchers demonstrated a new kind of trap to confine structured optical modes and to guide them on the chip.

In their “Science Advances” work, researchers show that, by slowly changing the pattern of metasurface in two directions, one can create optical resonators which trap structured light and radiate it. Interestingly, this underlying structure gave rise to unusual patterns of the radiated light – optical vortex beams.

Applying similar slow change in the pattern in one direction, as reported in “Nature Nanotechnology” work, researchers have created waveguided for structured light. These channels allow guiding optical signals while preserving the internal structure of light. As such, this is similar to the flow of currents in wires, if we could have wires with two flavors of charges.

Interestingly, such currents have been of enormous interest in electronics recently, and a completely new class of electronic devices, commonly referred to as spintronic or valleytronic, was envisioned. In such devices it is not the flow of charge by itself that would transfer signals, but spin or valley of electrons, which promises a plethora of advantages in comparison to conventional electronic devices.

Khanikaev’s work envisions a similar concept, but with light rather than electrons. However, in contrast to electronic systems, optics and photonics have one significant advantage – optical modes do not suffer from decoherence to the same degree as electrons, which can be vital for quantum technologies. The demonstrations by Khanikaev’s group can be useful for quantum applications for several reasons. Thus, the added structure of optical modes can be used to encode quantum information in the form of quantum bits. This information can then be transported on a chip or emitted into free space for communicating quantum information between remote systems. 

Moving in this direction, the Khanikaev group is currently working on implementing these ideas with quantum states of structured light and realizing quantum logic in their photonic nanostructures. 

About the City College of New York
Since 1847, The City College of New York has provided a high-quality and affordable education to generations of New Yorkers in a wide variety of disciplines. CCNY embraces its position at the forefront of social change. It is ranked #1 by the Harvard-based Opportunity Insights out of 369 selective public colleges in the United States on the overall mobility index. This measure reflects both access and outcomes, representing the likelihood that a student at CCNY can move up two or more income quintiles. Education research organization Degree Choices ranks CCNY #1 nationally among universities for economic return on investment. In addition, the Center for World University Rankings places CCNY in the top 1.8% of universities worldwide in terms of academic excellence. Labor analytics firm Emsi puts at $1.9 billion CCNY’s annual economic impact on the regional economy (5 boroughs and 5 adjacent counties) and quantifies the “for dollar” return on investment to students, taxpayers and society. At City College, more than 15,000 students pursue undergraduate and graduate degrees in eight schools and divisions, driven by significant funded research, creativity and scholarship. This year, CCNY launched its most expansive fundraising campaign, ever. The campaign, titled “Doing Remarkable Things Together” seeks to bring the College’s Foundation to more than $1 billion in total assets in support of the College mission. CCNY is as diverse, dynamic and visionary as New York City itself. View CCNY Media Kit.

Jay Mwamba
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