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Nanostructured Holograms Control Light’s Intensity, Phase, Polarization

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By combining cutting-edge nanotechnology with holograms, applied physicists at Harvard demonstrated a novel way for changing the intensity, phase and polarization of light rays.

The researchers at Harvard's School of Engineering and Applied Sciences (SEAS) used the holograms to create an unusual state of light called a radially polarized beam. These beams, which span the visible and near-IR spectrum, are important for applications like high-resolution lithography as well as trapping and manipulating tiny particles like viruses. This is the first time a single, simple device has been designed to control the intensity, phase and polarization of light at once.

Left: holographic component fabricated by ion milling with a focused ion beam a 150-nm-thick gold film deposited on a glass substrate. A laser beam is partially transformed into a radially polarized beam as it traverses the device. The wide grooves create the donut-shaped intensity profile, known as a vortex, while the subwavelength nanometer grooves in the inset determine locally the radial polarization, which is perpendicular to the grooves. Right: The computed characteristic beam cross-section; the blue arrows indicate the radial polarization.
Left: holographic component fabricated by ion milling with a focused ion beam a 150-nm-thick gold film deposited on a glass substrate. A laser beam is partially transformed into a radially polarized beam as it traverses the device. The wide grooves create the donut-shaped intensity profile, known as a vortex, while the subwavelength nanometer grooves in the inset determine locally the radial polarization, which is perpendicular to the grooves. Right: The computed characteristic beam cross-section; the blue arrows indicate the radial polarization. Courtesy of Federico Capasso.

“Our lab works on using nanotechnology to play with light,” said SEAS research associate Patrice Genevet. “In this research, we’ve used holography in a novel way, incorporating cutting-edge nanotechnology in the form of subwavelength structures at a scale of just tens of nanometers.”

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In recent years, Genevet and researchers in the laboratory of Federico Capasso, Robert L. Wallace Professor of Applied Physics and Vinton Hayes Senior Research Fellow in Electrical Engineering at SEAS, have focused on nanophotonics with the goal of creating new light beams and special effects that arise from the interaction of light with nanostructured materials.

Federico Capasso, the Robert L. Wallace Professor of Applied Physics and Vinton Hayes Senior Research Fellow in Electrical Engineering at Harvard SEAS.
Federico Capasso, the Robert L. Wallace Professor of Applied Physics and Vinton Hayes Senior Research Fellow in Electrical Engineering at Harvard SEAS. In his lab's latest research, they demonstrated that nanostructured holograms  can be used to change the intensity, phase and polarization of light rays. Courtesy Harvard SEAS.

“When light is radially polarized, its electromagnetic vibrations oscillate inward and outward from the center of the beam like the spokes of a wheel,” Capasso said. “This unusual beam manifests itself as a very intense ring of light with a dark spot in the center.

“It is noteworthy that the same nanostructured holographic plate can be used to create radially polarized light at so many different wavelengths. Radially polarized light can be focused much more tightly than conventionally polarized light, thus enabling many potential applications in microscopy and nanoparticle manipulation.”

The new device resembles a normal hologram grating with an additional nanostructured pattern carved into it. Visible light interacts differently with apertures textured on the nanoscale than with those on the scale of microns or larger. By exploiting these behaviors, the modular interface can bend incoming light to adjust its intensity, phase and polarization.

The polarization effect that the new interface has on light could formerly only be achieved by a cascade of several different optical elements. “Now, you can control everything you need with just a single interface,” Genevet said. “We’re gaining a big advantage in terms of saving space.”

For more information on this work, visit: www.seas.harvard.edu/capasso

Published: August 2013
Glossary
intensity
Flux per unit solid angle.
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
phase
In optics and photonics, "phase" refers to a property of electromagnetic waves, such as light, that describes the position of a wave at a given point in time within its oscillation cycle. More specifically, it indicates the position of a wave relative to a reference point, typically the starting point of a cycle. When discussing phase in optics, it's often described in terms of the phase difference between two waves or the phase of a single wave. The phase difference between two waves is the...
polarization
Polarization refers to the orientation of oscillations in a transverse wave, such as light waves, radio waves, or other electromagnetic waves. In simpler terms, it describes the direction in which the electric field vector of a wave vibrates. Understanding polarization is important in various fields, including optics, telecommunications, and physics. Key points about polarization: Transverse waves: Polarization is a concept associated with transverse waves, where the oscillations occur...
AmericasFederico CapassoHarvard School of Engineering and Applied ScienceshologramsImagingindustrialintensityLasersMassachusettsMicroscopynanonanostructureOpticsPatrice Genevetphasepolarizationradially polarized lightResearch & TechnologySEAS

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