Optical Waveguides in Photonic Crystals

KeelSpawn sent in a short article talking about creating the equivalent of etched silicon for light, using a method intended to be cheap enough for commercial applications.

Re:costs $$$

[jejones]

Braun's referring to the other guys' method, not his. Braun's method is cheaper.

Entertainment applications?

[ipmcc]

Although this is obviously aimed at more "business-productive" markets, I'd be interested to see how (or if) this technology affects the entertainment industry. Just yesterday, on the star wars topic, we saw lots of good banter about DLP, which is made up of millions of minature mirrors. I wonder if technology like this could take the mechanics out of something like DLP. Or perhaps, on a further refinement, this technology could supercede the entire concept of things like galvanometers in things like laser shows.

The major obstacle here seems to be cost, but what if making the waveguides so small wasnt the challenge?

Improves your overall internet experiance

[oliverthered]

Wave guides that small are useless, you need big wave guides to improve the experiance of surfing the net.

Substitution?

[grondak]

I just hope the ad guys don't make a mistake and try to substitute photonic crystals for my coffee!

I have a DLP projector.

[CrystalFalcon]

Sad I missed that on the Star Wars thread, as I have a DLP projector for my home theater system and therefore some hands-on experience from them. Anyway, what can be said about them is;

- less color saturation than LCD projection (colors are not as vivid)
- no burn-in (as opposed to LCD)
- better longevity of colors (no fade over time)
- MUCH better brightness, in fact, black becomes dark-grayish (this is a problem)
- bulbs cost you an arm and a leg
- less need for cooling => less noise
- crispness is so good you have to deliberately DE-focus to get a good movie viewing experience

Everything of course from my own personal experience with them. I could recommend a DLP projector to anyone who wants to set up a home system.

Re:I have a DLP projector.

[CrystalFalcon]

Digital Light Processing. A lame abbreviation if there ever was one. :-) A Texas Instruments technology, anyway.

The equivalent, or the same as

[gewalker]

The article does say that the current process is based on a laser etching in a polymer, but Paul Braun also suggests that the ultimate goal of usefulness will would probably be made of a material "such as silicon" that transmit light more reliably.

I fail to see a huge advantage in a photonics circuit based on this technology. Braun has perhaps developed a new method that could replace the complex multistep photochemical etching process of todays microprocessors. But it would appear to be harder to scale for production if the laser has to draw the circuit (or the inverse of the circuit) on the chip. Its like the difference between stamping a CD & burning a CDR. Stamping scales for production, and burning one at a time does not. Could be a real innovation for small-run custom circuits, but that does not seem to be where the money is.

Re:The equivalent, or the same as

[Zelet]

No, in this case the laser process is cheaper and more reliable. One reason for this, as stated in the article, is that there is only one pass of the laser to make the pathways. The difference is that the current "complex multistep photochemical etching process" is just that complex and multistep.

Re:Trek

[Psion]

HA! I remember an article in Byte magazine from ten or so years ago detailing a holographic terabyte storage medium on a piece of glass the size and shape of a microscope slide -- hows that for your isolinear chip? The article said such devices could be available for commercial use within one to three years.

One must approach these kinds of announcements with a degree of skepticism. Sometimes they are little more than fishing expeditions intended to drum up a little shareholder interest. Sometimes, they are completely legitimate, but other market pressures prevent the technologies from coming out in anything close to the stated time frame.

Not that I disagree in any way with your solid state goal! I'm with you 99.9997% on that one!

Re:What about applications?

[Drakula]

Probably the biggest application for this technology will be optoelectronic integrated circuits. One of the things that makes optical communications so expense and limits there speed is the need to convert from a light signal to an electronic signal and vice versa. Not only are electronic cictuits slower than there optical counter parts, all the separate modules are expensive. This technology would reduce the need for conversion, at least part of the time, by allowing one to make optical circuits instead. Once that can be done, integrating the wave guides, pump lasers, and amplifiers would be not too far down the road. This could make fiber to the home a reality.

a brief intro to photonic crystals

[stevenj]

Since I actually do research in this area and there is some confusion here, let me give a very brief introduction to photonic crystals (which can be studied using free software).

Photonic crystals are periodically-structured optical media that, with the right structure, completely forbid the propagation of light in a certain range of wavelengths (analogous to electronic band gaps). They form a sort of "optical insulator" that you can use to trap, guide, and control light. The work at essentially any wavelength (in contrast to metallic waveguides) provided that you can fabricate a periodic structure with periodicity on the order of half a wavelength, and have a number of potential applications, including:

• Integrated optics: optimally miniaturized networks of optical devices to offload some analog signal-processing or telecommunications tasks, circumventing e.g. bandwidth limitations of electronic circuits. (Few these days are predicting all-optical computers.)
• Optical fibers (from 2d or 1d patterns) that circumvent fundamental loss/nonlinearity/PMD limits of silica fiber, and for other novel applications (e.g. high-power or highly-nonlinear fiber devices).
• More-efficient LEDs and lasers, both by enhancing the optical density of states and by making the light go where you want it to go.
• Slow-light devices for time-delays, nonlinear interactions...
• Super-lenses (that can focus beyond the diffraction limit via negative effective indices of refraction).
• Super-prisms (very wavelength-sensitive refraction, e.g. for wavelength demultiplexing).
• ...

1d photonic crystals (multilayer films) have been known since Rayleigh in 1887 (although there are new twists) but 2d and 3d crystals weren't conceived until 1987, via a marriage of solid-state physics and electromagnetism.

The paper Slashdot linked to is considering photonic-crystals made by self-assembly of microspheres into close-packed lattices. A perfect crystal has limited use; you need to make defects to carve devices out of it, and that is what they are doing here. (There are many problems of precision, etcetera, that still need to be overcome for practical integrated devices, I think.)

Note that one can also make photonic crystals with traditional lithography, but that poses its own set of challenges (especially for full 3d-periodic crystals).