Graphene Sheath Modulates Fiber-Optic Transmission At 200 GHz 18
An anonymous reader writes "Researchers in China have shown that a graphene sheath can modulate light transmission through an optical fiber at 200 GHz. The graphene, even crudely draped over the optic fiber on a microscope slide, absorbed some of the light passing through the fiber. But a preceding short-wavelength light pulse could temporarily disable the effect, enabling an all-optical infrared fiber-optic switch. Recovery was fast enough to enable modulation of transmitted light at 200 GHz using conventional fiber-optic communication wavelengths and thinned commercial telecommunications fibers. The findings could have use in telecommunications industry and future high-speed on-chip optical interconnects."
And on the far end? (Score:5, Interesting)
It sounds like this is just very high speed On Off Keying, which is not only limited by modulation but also by the ability to clearly receive that signal on the far end.
This could be an alternative to coherent phase shift keying as a short range 100G+ interconnect though, where dispersion and noise aren't an issue.
Re:And on the far end? (Score:5, Informative)
Another key benefit would be the simplification of encoding/decoding hardware. Using coherent PSK, QAM and other schemes there's quite a bit of effort put into determining the channel, etc to be able to know your current place in the constellation which can be a problem in the presence of noise sources. There's the well-known algorithms, tons of proprietary ones and new research papers every day on ways to betermine estimate the transmission channel to allow for more points (bits) in a constellation. Some of the QAM's, after disruption take over 100,000 symbols to re-lock to the bit stream. But that's the price you pay to shove more data down the pipe. If this works well though, you can get rid of all of that logic, stringent requirements on the transmission media and improve immunity to noise because with a simple AM, it only takes one symbol to re-lock onto the bit stream. They're dead simple to implement and robust as can be.
I can definitely see some really big uses for this if all goes well.
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It's modulation depth (per the abstract) is only 38%, so it's not quite a broad-band as on-off-keying.
Once you've got that it's trivial to use beam splitters and destructive interference to change the modulation from 62% vs. 100% to 38% vs. essentially 0% amplitude.
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It's modulation depth (per the abstract) is only 38%, so it's not quite a broad-band as on-off-keying.
Once you've got that it's trivial to use beam splitters and destructive interference to change the modulation from 62% vs. 100% to 38% vs. essentially 0% amplitude.
Not that it matters: The receiver is AC coupled, anyhow. As long as the modulation is sufficiently deep that the signal is substantially above the noise floor, you're fine. Switching a third of the amplitude is nearly as good as switching all
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chops up the chip density some (Score:4, Interesting)
you also have to dissipate the heat of conversion in the source and detector, which means large chunks of silicon in relation to the transistors. but I can see using this to cut distortion cross-chip, or up a stack of chips in Cray-ish constructions, and maintain internal speed.
there is of course the usual last line of the study document, on behalf of the lead and the graduate assistants who have several years to go in their degree yet, that "this effect needs more study."
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Well, to modulate an electric current you need an electric current (that's how a transistor works). Amplification isn't done by increasing the voltage/current of the reference signal. You use the reference signal to modulate a higher voltage/current. Once you have a transistor-equivalent we know how to use that to do all kinds of interesting things.
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It's graphene all the way down.
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Graphene. How does it work?
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Your next PC will require a pilot light.
This is a Proof-Of Concept stage report. (Score:1)