Terahertz - From Physics to Life

See here and here; using the E8 mathematical structure, a man by the name of Garrett Lisi has proposed a new model of physics that basically explains the Standard Model and predicts a few new particles that the LHC may be able to detect next year. This sounds cool. Here’s his paper. Oh also, since it uses only the geometry he did this without calculus!

Note: This is technically not peer-reviewed research yet, it has only been submitted online to a free online paper-publishing site, so holes may yet be found, or not.

This past weekend I attended the Canadian Undergraduate Physics Conference at Simon Fraser University in Vancouver (and Burnaby), British Columbia, and it was a hoot!

What tops my list is hearing the talk from Dr. Lene Hau who used Bose-Einstein Condensates to slow, stop, and even transport light!  This has gotten me interested in the entire field of BEC and atom trapping and I’m now in contact with Dr. Kirk Madison at UBC about a potential summer job in his lab next year (and maybe grad school after).

I must complain that the majority of the people I met from the University of Calgary were tremendous douchebags - and I don’t say that out of a school rivalry.  We listened to one of their talks (which wasn’t even that good), and midway through he insulted another university (over a plagiarism scandal that was likely unrelated to the paper he was referencing) and after he muttered that the audience was “boring” when they didn’t ask him any questions.  Another guy from their school was running through the hall on our floor and some chick yelled “you’re a nice guy, I just don’t want to fuck you” (or something to that extent), who also is rumoured to have gotten his funding cut for getting a tattoo when he was supposed to be presenting his poster (which was pretty abhorrent - ie. didn’t present anything expect what sounded like a dreamt up unresearched paradox, handdrawn, with links to pictures).  And even in talking with them they were just not nice.  We did meet one nice UofC Physics guy, so I don’t want to shame them all, just the majority of them.

As for the rest of the conference though, it was fantastic.  We saw TRIUMF and SFU Physics labs.  I presented and was later told by someone that he heard my talk was good - as in someone passed along good words about my talk.  Overall it was a great experience.

Terahertz radiation is electromagnetic radiation of frequencies between 10 GHz and 30 Thz (in the lab). THz = 10¹² Hz This puts it in the far-infrared part of the spectrum with wavelengths (in case you can’t do the math) on the order of 100 microns.

This part of the spectrum is interesting because it lies in what’s known as the “THz gap” between traditional photonics and microwave technologies. Traditional electronics cannot switch fast enough to generate these pulses, and commercial lasers cannot generate that low of frequency of waves.

So how do we generate these waves? This is where ultrafast optics comes in. Using a technique called “modelocking” a standing wave is setup in a laser cavity and waves constructively interfere to create pulses with lengths on the order of femtoseconds (10^-15 s). These pulses can then be amplified in a multi-pass system and set into a specific repetition rate (1080 Hz in my lab). Each ~100 fs pulse contains approximately 1/2 mJ. These pulses are then of high enough intensity to cause nonlinear effects in most materials. We now enter nonlinear optics land. When this light is incident on specific nonlinear crystals (in our case Zinc Telluride), a second order nonlinear effect called optical rectification occurs. This effect essentially creates a DC bias inside the crystal and current essentially flows through the crystal itself. This accelerating currents creates electromagnetic radiation in the THz regime.

THz pulses are interesting to study due to their absorption properties. Water is the primary absorber of these wavelengths, while plastics, papers, and fabrics have much lower absorption amounts. This allows for the application of techniques for THz imaging. For instance a THz wave can scan through clothes but gets absorbed by water or reflected by metal. This allows for the potential use of security scanning where police can essentially ’see’ through a person’s clothes and determine if there are any weapons on them. The resolution is better than 1 mm, which is good enough to see most weapons. The following image shows a THz imaging scan:

There are several other ways to generate THz radiation (which I am presently working on a few), as well as many more applications (inlcuding THz-TDS). It is an exciting field that I am enjoying as I learn more about it.