Twisted light beam in vacuum travels 0.1% slower than the speed of light

March 24, 2016
This unusual characteristic of some optical vortex beams holds important implications for quantum communication.

Researchers at the University of Ottawa (Ottawa, ON, Canada) observed that twisted light (also known as an optical vortex) in a vacuum travels slower than the universal physical constant established as the speed of light by Einstein's theory of relativity.1 Twisted light, which turns around its axis of travel much like a corkscrew, holds potential for storing information for quantum computing and communications applications.

The researchers report that twisted light pulses in a vacuum travel up to 0.1% slower than the 299,792,458 m/s speed of light. This is the first time that scientists have shown that twisting light can slow it down in a vacuum.

"Anyone who wants to use twisted light for quantum communication should be aware of this effect," says Ebrahim Karimi, assistant professor at the University of Ottawa and leader of the research team. "If they don't compensate for the slow-light effect, information coded on twisted light might not arrive in the right order. Propagation speeds can significantly affect many protocols related to quantum communication."

Benefits of twisted light

Ebrahim Karimi and Frederic Bouchard, two of the researchers, are studying twisted light because of its great potential for quantum communication and quantum computers. Today, light is used to encode information by either varying the number of photons emitted or switching between light's two polarization states. Twisted light offers the advantage that each twist can encode a different bit, allowing the encoding of a great deal more information using less light. Twisted light might one day offer a quantum-based communication method that uses less energy and is more secure than today's methods.

The researchers first noticed the slow speed of twisted light when conducting experiments with Gaussian laser light and light with 10 twists. "We realized that the two beams didn’t arrive at the detector at the same time," Karimi says. "The twisted light was slower, which was surprising until we realized that the twists make the beam tilt slightly as it propagates. This tilt means that the twisted light beam doesn’t take the straightest, and thus fastest, path between two points."

Measuring the delay

The scientists set about the challenging task of measuring the delay, which they calculated to be on the order of tenths of a femtosecond. After a year of searching for a capable measurement method, they connected with nonlinear-optics scientists who suggested they modify the approach known as frequency-resolved optical gating (FROG) that is used to measure ultrashort laser pulses.

Using the modified FROG approach, Karimi's research team worked with Robert Boyd's team, also at the University of Ottawa, to compare Gaussian beams with different types of twisted light. They found that increasing the number of twists further slowed the light. They measured delays as long as 23 fs for the twisted light beams.

"The type of precision that can be measured using FROG was not previously used in the quantum optics community, and thus scientists in this area were not aware that twisted light traveled slower than the speed of light," Karimi says.

Speeding up light?

If it's possible to slow the speed of light by altering its structure, it may also be possible to speed up light, according to the researchers. The researchers are now planning to use FROG to measure other types of structured light that their calculations have predicted may travel very slightly faster than the speed of light in a vacuum.

Source: http://www.osa.org/en-us/about_osa/newsroom/news_releases/2016/slowing_down_light_with_a_twist/

REFERENCE:

F. Bouchard et al., Optica, 3, 4, 351 (2016). doi: 10.1364/optica.3.000351

About the Author

John Wallace | Senior Technical Editor (1998-2022)

John Wallace was with Laser Focus World for nearly 25 years, retiring in late June 2022. He obtained a bachelor's degree in mechanical engineering and physics at Rutgers University and a master's in optical engineering at the University of Rochester. Before becoming an editor, John worked as an engineer at RCA, Exxon, Eastman Kodak, and GCA Corporation.

Sponsored Recommendations

How to Tune Servo Systems: Force Control

Oct. 23, 2024
Tuning the servo system to meet or exceed the performance specification can be a troubling task, join our webinar to learn to optimize performance.

Laser Machining: Dynamic Error Reduction via Galvo Compensation

Oct. 23, 2024
A common misconception is that high throughput implies higher speeds, but the real factor that impacts throughput is higher accelerations. Read more here!

Boost Productivity and Process Quality in High-Performance Laser Processing

Oct. 23, 2024
Read a discussion about developments in high-dynamic laser processing that improve process throughput and part quality.

Precision Automation Technologies that Minimize Laser Cut Hypotube Manufacturing Risk

Oct. 23, 2024
In this webinar, you will discover the precision automation technologies essential for manufacturing high-quality laser-cut hypotubes. Learn key processes, techniques, and best...

Voice your opinion!

To join the conversation, and become an exclusive member of Laser Focus World, create an account today!