Researchers make better sense of incoherent light
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Researchers make better sense of incoherent light
Researchers make better sense of incoherent light
September 16, 2016 by Kevin Stacey
A new technique detects spatial coherence in light at smaller scales than had been possible. The image shows visibility curves appearing at the nanoscale, the telltale sign of spatial coherence. Credit: Pacifici Lab / Brown University
One of the differences between lasers and desk lamps is that laser light is spatially coherent, meaning the peaks and valleys of the light waves are correlated with each other. The jumbled, uncorrelated waves coming from a desk lamp, on the other hand, are often said to be incoherent.
That's a bit of a misnomer, however. In theory, virtually all light—even "incoherent" light—can have a high degree of spatial coherence. But detecting that coherence requires probing light at extremely small length scales that cannot be accessed using traditional techniques.
Now, researchers in the lab of Domenico Pacifici, professor in Brown University's School of Engineering, have found a way to detect spatial coherence in light beams at the scale of a few hundred nanometers—a much smaller scale than has ever been possible. The research provides the first experimental verification of optical coherence theory at the nanoscale.
"There's a very small length scale at which light that's often said to be incoherent behaves coherently, but we've lacked experimental techniques to quantify it," said Drew Morrill, lead author of an article describing the new research. "That degree of coherence contains meaningful information we can now access, which could be useful in characterizing light sources and potentially for new imaging and microscopy techniques."
Morrill, now a graduate student at the University of Colorado, performed the work as an undergraduate at Brown. The research paper, coauthored with Pacifici and Brown postdoctoral scholar Dongfang Li, is published in Nature Photonics.
Traditional methods for testing the extent to which light is spatially coherent involve devices that can split the wavefront of a light beam. The most famous of these is the Young interferometer, also known as the double slit experiment. The experiment consists of a light source aimed at a detector screen, with an opaque barrier between the two. The barrier has two small slits in it, allowing two rays of light to pass through. As the two rays emerge from the slits, some of the light waves are bent toward each other, causing them to recombine. Recombining waves that are coherent will create an interference pattern—a series of light and dark patches—on the detector screen. By measuring the contrast of those light and dark patches, researchers can quantify the light's coherence.
The problem is that for light sources with very low spatial coherence, the double slit experiment doesn't work as well because the length scales at which the interference patterns appear is very small. Producing interference over small length scales requires the two slits to be placed very close together. But when the distance between the two slits gets close to of the wavelength of the light shown upon them, the experiment breaks down. The interferometer can no longer split and recombine the beam properly to look for interference.
"The interference fringes are smeared out, making it difficult to quantify the degree of coherence," Morrill said. "But if you could get around the fundamental limitations of the double slit experiment, theoretically you should be able to see those fringes."
To get around those limitations, the researchers employed a different kind of interferometer that makes use of plasmonics, the interaction between light and electrons in a metal. Instead of two slits, the plasmonic interferometer has a slit and a groove in a surface made of silver. Light hitting the groove creates a surface plasmon polariton (SPP), a density wave of electrons moving across the silver surface. The SPP propagates toward the slit, where it recombines with the light going through the slit. Because the SPP is related to the original beam of light but has a smaller wavelength, and because it diffracts at a 90-degree angle toward the slit, the groove and slit in the plasmonic interferometer can be placed closer together than the two slits in the Young interferometer.
...
"We're providing scientists with a new tool to quantify the degree of coherence of light at a length scale that hadn't been possible before," Pacifici said.
Explore further: On a wire or in a fiber, a wave is a wave
More information: Drew Morrill et al. Measuring subwavelength spatial coherence with plasmonic interferometry, Nature Photonics (2016). DOI: 10.1038/nphoton.2016.162
Journal reference: Nature Photonics search and more info website
Provided by: Brown University search and more info website
Read more at: http://phys.org/news/2016-09-incoherent.html#jCp
September 16, 2016 by Kevin Stacey
A new technique detects spatial coherence in light at smaller scales than had been possible. The image shows visibility curves appearing at the nanoscale, the telltale sign of spatial coherence. Credit: Pacifici Lab / Brown University
One of the differences between lasers and desk lamps is that laser light is spatially coherent, meaning the peaks and valleys of the light waves are correlated with each other. The jumbled, uncorrelated waves coming from a desk lamp, on the other hand, are often said to be incoherent.
That's a bit of a misnomer, however. In theory, virtually all light—even "incoherent" light—can have a high degree of spatial coherence. But detecting that coherence requires probing light at extremely small length scales that cannot be accessed using traditional techniques.
Now, researchers in the lab of Domenico Pacifici, professor in Brown University's School of Engineering, have found a way to detect spatial coherence in light beams at the scale of a few hundred nanometers—a much smaller scale than has ever been possible. The research provides the first experimental verification of optical coherence theory at the nanoscale.
"There's a very small length scale at which light that's often said to be incoherent behaves coherently, but we've lacked experimental techniques to quantify it," said Drew Morrill, lead author of an article describing the new research. "That degree of coherence contains meaningful information we can now access, which could be useful in characterizing light sources and potentially for new imaging and microscopy techniques."
Morrill, now a graduate student at the University of Colorado, performed the work as an undergraduate at Brown. The research paper, coauthored with Pacifici and Brown postdoctoral scholar Dongfang Li, is published in Nature Photonics.
Traditional methods for testing the extent to which light is spatially coherent involve devices that can split the wavefront of a light beam. The most famous of these is the Young interferometer, also known as the double slit experiment. The experiment consists of a light source aimed at a detector screen, with an opaque barrier between the two. The barrier has two small slits in it, allowing two rays of light to pass through. As the two rays emerge from the slits, some of the light waves are bent toward each other, causing them to recombine. Recombining waves that are coherent will create an interference pattern—a series of light and dark patches—on the detector screen. By measuring the contrast of those light and dark patches, researchers can quantify the light's coherence.
The problem is that for light sources with very low spatial coherence, the double slit experiment doesn't work as well because the length scales at which the interference patterns appear is very small. Producing interference over small length scales requires the two slits to be placed very close together. But when the distance between the two slits gets close to of the wavelength of the light shown upon them, the experiment breaks down. The interferometer can no longer split and recombine the beam properly to look for interference.
"The interference fringes are smeared out, making it difficult to quantify the degree of coherence," Morrill said. "But if you could get around the fundamental limitations of the double slit experiment, theoretically you should be able to see those fringes."
To get around those limitations, the researchers employed a different kind of interferometer that makes use of plasmonics, the interaction between light and electrons in a metal. Instead of two slits, the plasmonic interferometer has a slit and a groove in a surface made of silver. Light hitting the groove creates a surface plasmon polariton (SPP), a density wave of electrons moving across the silver surface. The SPP propagates toward the slit, where it recombines with the light going through the slit. Because the SPP is related to the original beam of light but has a smaller wavelength, and because it diffracts at a 90-degree angle toward the slit, the groove and slit in the plasmonic interferometer can be placed closer together than the two slits in the Young interferometer.
...
"We're providing scientists with a new tool to quantify the degree of coherence of light at a length scale that hadn't been possible before," Pacifici said.
Explore further: On a wire or in a fiber, a wave is a wave
More information: Drew Morrill et al. Measuring subwavelength spatial coherence with plasmonic interferometry, Nature Photonics (2016). DOI: 10.1038/nphoton.2016.162
Journal reference: Nature Photonics search and more info website
Provided by: Brown University search and more info website
Read more at: http://phys.org/news/2016-09-incoherent.html#jCp
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