That smile. That presence. That fashion sense. Yup, Richard Feynman. First we’re published together in the CRC Handbook of Nanotech, now we find ourselves playing the same second fiddles on the same page to the infinitely more photogenic Giselle Itiê. Not bad, considering he checked out before I entered my teens.

I have no idea what Pablo Nogueira’s article says, but I do know that the folks at Revista Latitude (that’s Latitude Magazine!) spiced the text up with a few primo images available from Rocky Rawstern’s much appreciated nanotech-now.com gallery. Revista Latitude and Revista Top are very visual magazines. The now-ness of a Rolling Stone with the imagery of a National Geographic. I didn’t understand a word but I much enjoyed turning the pages. It does a researcher good to see that a magazine can make science work in same binding with photojournals of exotic destinations or fashion on location.

Calfskin bongos, international models, molecular nanotechnology. I think anyone who finished “Surely You Must Be Joking” would conclude that the man would approve.

www.topmagazine.com.br
www.feynmanonline.com
www.nanotech-now.com
en.wikipedia.org/wiki/Richard_Feynman

I mentioned in a previous post about the good news being had by Mark and family with his Qubits building blocks. His toys (and graphics, which are also excellent) are featured on the main page of renderosity.com, a computer graphics art community site (there really is other content on the site besides hi-res women’s fashion (or lack thereof)). Now everyone can see what it was I was talking about (and why not yet another google hit for the Qubits website?). The article feedback is looking pretty positive as well.

Despite Marsha Carlson’s best efforts, I still don’t quote well. Fortunately, they managed to switch the order of my first and middle name (I oft’ wonder why the “Gregory” shows up everywhere), so people might wind up mistaking me for someone else.

Just for the sake of keeping records, a pdf of the article is available HERE.

www.renderosity.com/news.php?viewStory=12961
www.qubits.com
www.myspace.com/djrazorsharp

More free press concerning the HMX paper in J.Phys.Chem. A. in the form of “THz spectrum yields to theory” in the Science and Technology Concentrates section of C&E News (February 6, 2006, Volume 84, Number 6, p. 25). ACS-only accessible if you’re not on a campus with a subscription. Incidentally, the editor who made us look good, Mitch Jacoby, also received some free press lately doing something I wish I was doing more often. Check’em out at www.thewayjewsrock.com.

pubs.acs.org/journals/jpcafh/index.html
pubs.acs.org/cen
terahertz.syr.edu
www.thewayjewsrock.com

Six years as a card-carrying member finally paid off this week as my new favorite editor Gilbert Chin selected the HMX THz DFT paper (posted below) that just came out in J. Phys. Chem. A as an AOK Editor’s Choice in Science magazine. So far as I know, this page is publicly accessible without subscription, although I do encourage you to join the A.A.A.S. and help us all push this boulder that is U.S. research up the North face of Mt. Everest.

“So what?” you may ask. Terahertz (THz) spectroscopy is a technique that allows one to study vibrations in the zero-ish to few hundred wavenumber region, which is exactly where molecules undergo their largest-amplitude, lowest-frequency motions. I made mention back in an NCSA Access Magazine article concerning the same subject (regarding neutron spectroscopy) that…

“Molecules feel the same physical constraints from crystal packing that someone on the subway would from other passengers. If you take that person on the subway and put them on a bumpy track, where they move and how far they move will be determined by where everyone else is. Their restricted motion on a crowded subway will look very different to an observer than their motion on a bumpy track if the car was empty of other people. We see those differences when comparing vibrational spectra of isolated molecules with crystalline solids and, therefore, learn about the environment of the molecule in the crystal.”

When the molecules aren’t involved in strong electrostatic interactions, the high frequency molecular vibrational modes in crystals usually occur close to the gas-phase molecular vibrational frequency. That is to say, peaks shift somewhat, but they usually reside close to their gas-phase values. In the low-frequency molecular modes (to 300 cm-1 or so), having an array of neighboring molecules closely spaced to one another DOES affect the positions of molecular vibrations, because these large-amplitude motions occur in constrained environments. There’s a difference between kicking out your leg and twiddling your fingers in an elevator. Further, the molecular vibrations within a molecular crystal cell are not only a result of molecular motions, but also the relative motions between neighboring molecules, which isolated-molecule calculations, surprise, can’t account for. Having two neighboring molecules rotate clockwise is different than having one rotate clockwise and the other counterclockwise. The 3 translational and 3 rotational motions molecular vibrational spectroscopists throw out in their 3n-6 mode count are THE motions of impact in the phonon region. In the figure below, the red lines are the molecular normal modes calculated at a VWNBP/DNP level of theory. The blue lines are the normal modes of the crystal cell at the same theory level, which show much more structure. The smooth blue line is a simple Lorentzian lineshape of the calculated solid-state modes.

So, for the scientists who didn’t go “well, yeah”, it is shown that theory-based solid-state THz spectroscopy assignments are suspect (at best, useless at worst) when not performed by solid-state quantum chemical methods. For everyone else, there’s little need to detail in this day and age the utility of detecting high-energy explosives by… non-invasive spectroscopic (at a distance!) methods.

I also find it mildly amusing that the experimental THz piece is under physics, and the theoretical THz piece is under chemistry.

www.sciencemag.org/content/vol311/issue5761/twil.dtl
pubs.acs.org/journals/jpcafh/index.html
access.ncsa.uiuc.edu/Stories/crystalforms