UCLA Researchers Demo First Silicon Laser

An anonymous reader submits "Researchers at University of California, LA have demonstrated the first silicon laser. The lack of a silicon laser has been a major roadblock in the progress of silicon optoelectronics and photonics. This development shows that despite popular belief, a laser can indeed be made on a silicon chip. Modern electronic computers are getting closer to being optical in any case (gigahertz range). This discovery makes optical computers much closer to reality."

For once don't RTFA...

[TheLink]

Cue the Raman effect jokes...

Re:*First* silicon laser? - YES.

[rco3]

No, they aren't made of silicon. They're usually made of compound semiconductors, such as gallium arsenide, etc.

Re:*First* silicon laser? - YES.

[JGski]

Traditional semiconductor lasers (and LEDs) use carrier (electrons/holes) energy transitions to ground state to emit photons. Silicon is an indirect bandgap semiconductor so carriers falling back to ground state require a phonon (quantum lattice vibration) of the right energy/spectra to create a photon - which with regular Si has an extremely probability of showing up at the critical moment for a photon emission - so instead the energy is dissipated as heat (phonons) rather than light (photons). Direct ga

No cooling?

[floydman]

From the UCLA [ucla.edu] "A key attribute of the new technology is that it can produce mid-infrared radiation without any cooling," Jalali said

Now this sounds really intersting, how come they dont need cooling?

Re:No cooling?

[TykeClone]

Their using Pentium 4 heatsinks in series.

Re:No cooling?

[gl4ss]

because it's meant to produce heat :p

Also in spite of...

[hackwrench]

Santa Claus, The Tooth Fairy, and The Easter Bunny, not to mention the sun rising and setting.

Re:Modern electronic computers are getting closer.

[Christopher Thomas]

Modern electronic computers are getting closer to being optical in any case (gigahertz range).

Could someone explain this to me? I don't get it.

It refers to a couple of things.

One is that people have been talking about using optics to route signals on motherboards for a long time, as high-frequency electrical signals are a pain to keep clean over the relatively long distances invovled. I'm skeptical of this happening any time soon, for the same reason I'm skeptical of CMOS-on-silicon dying any time soo

Re:Modern electronic computers are getting closer.

[sfp2322]

The Silicon laser isn't working with population inversion, it is based on the Raman effect - a nonlinear process. Pump photons are converted to photons with a lower energy given a phonon (a lattice vibration at 15.6 THz in this case). The laser works because the fact that Silicon is NOT strongly absorptive at the lasing wavelength. The lasing wavelength is 1650nm if I recall correctly. The bandgap of Silicon is ~1100nm. So there is no way that Silicon can be used to detect this light. Bandgap engineering o

Re:Modern electronic computers are getting closer.

[NetKraft]

Means the clock frequencies of modern processors are approaching the frequency range of visible light.

Re:Modern electronic computers are getting closer.

[NetKraft]

Or I could be just talking out of my ass, the optical frequencies are actually almost into the petahertz range. Sorry 'bout that, the "(gigahertz range)" thingy fooled me. Should've checked the actual figures first.

One Question

[Skynet]

But can it be attached to a sharks head?

Re:One Question

[Muhammar]

No - but it can be attached to leather goddesses. (The are terrible. The only concievable defense against them are tit-seeking missiles.)

Low repetition rate and external pumping

[Anonymous Coward]

This is nowhere near practical for integrated photonics. For one, the repetition rate is limited by the free carrier lifetime, which can range anywhere from about a nanosecond to several hundred nanoseconds, depending on how the waveguides are fabricated. So, the fastest the pulses can be repeated is about 1 GHz. Which is just slow even by todays standards. In this work they didn't even do that good, they repeated it at 25 MHZ. Slooow! And second, and the biggest problem, the Raman effect relies on an

Emitting light with silicon.

[Christopher Thomas]

And at this point there is no other easy way to make a silicon laser using anything other than the raman effect. Any other method would require the use of exotic materials (i.e. erbium, heterojunctions, etc.). It's been tried and the results aren't all that promising.

Actually, it turns out that if you can produce structures small enough, you can get silicon acting like something closer to a direct-bandgap material (you no longer have a crystal of near-infinite extent, so energy level analysis changes).

Th

Re:Emitting light with silicon.

[Christopher Thomas]

As far as I know I don't think anyone has been able to demonstrate lasing in silicon nanocrystals. Gain has been demonstrated but too many issues arise that prevent lasing. Also, electrical pumping is pretty much impossible at since the nanocrystals are embedded in an insulator (SiO2). Anything based on optical pumping will never be cheap and scalable.

This wasn't silicon nanocrystals - this was microstructures (though "micro" is a misnomer at scales this fine) in bulk silicon. Electrically driven silicon

Er. Baby chatter in slashdot. How ordinary....

[Fallen Andy]

>Modern electronic computers are getting closer to >being optical in any case (gigahertz range).

Huh, last time I checked lasers were up there in the *TERA* hertz range.

So what is the punchline here?
If the poster means we need faster interconnects, then yeah verily, but that isn't the problem for CPU
design. Feeding the buggers is. Since the 386 we haven't had memory which could keep them without grumbly tummy syndrome. Intel tried to lie to everybody about this, but even they eventually caved in and

Solution to the Wiring Problem

[reporter]

A laser on silicon essentially solves the wiring problem of traditional digital integrated circuits (ICs). Modern digital ICs consist mostly of wires; a small percentage of the silicon area is the transistors that perform the computation.

Two problems arise. Driving a signal from one end of the chip to the other end is very slow because the wires present a high RC load to the puny transistor. The other problem is simply routing the wires.

The laser solves the first problem because we can simply transmi

Problems with this solution.

[Christopher Thomas]

A laser on silicon essentially solves the wiring problem of traditional digital integrated circuits (ICs). Modern digital ICs consist mostly of wires; a small percentage of the silicon area is the transistors that perform the computation.

Not true last I checked, and I am presently doing IC design. Yes, you need plenty of space for your routing channels, but especially with the number of metal layers we have now, there's plenty of space _above_ the active circuitry even after you take out the layers used f

Fun

[Awestruckin]

Will this make laser tag more fun?