15min:

SIEGHARD ALBERT, KAREN KEPPLER ALBERT, MARTIN QUACK, PHYSICAL CHEMISTRY, ETH ZÜRICH, CH-8093 ZÜRICH, SWITZERLAND; RYAN P. A. BETTENS, DEPARTMENT OF CHEMISTRY, NATIONAL UNIVERSITY OF SINGAPORE, SINGAPORE 117543, SINGAPORE; FRANK C. DE LUCIA, DEPARTMENT OF PHYSICS, THE OHIO STATE UNIVERSITY, COLUMBUS, OHIO 43210, U.S.A..

One of the great challenges of modern high resolution infrared spectroscopy is the recording and the analysis of rotationally resolved spectra of relatively heavy molecules containing numerous vibrational modes. Here we present new results on the prototype heterocyclic molecule of pyridine. This molecule is of astrophysical interest and can be related to other nitrogen containing biological aromatic systems. Up to now only vibrationally resolved infrared spectra and rotational spectra exist, including recent FASSST spectra.

We have recorded the spectrum of pyridine in the region 600-1300~cm^-1 with our Zürich Bruker 2001 prototype Fourier transform infrared spectrometer\footnote S.~Albert, K.K. Albert, and M.~Quack, Trends in Optics and Photonics , 84 177 (2003),
S.~Albert, H.~Hollenstein, M.~Quack and M.~Willeke, Mol.~Phys. , 102, 1671 (2004). with an instrumental resolution of 0.0007~cm^-1, essentially Doppler limited, with Doppler widths ranging from 0.0008 to 0.0018~cm^-1. The analysis of the bands located at _c=700.2528~cm^-1 ( ₁₁), _c=744.0046~cm^-1 ( ₄) and _c=1031.6339~cm^-1 ( ₁₂) will be discussed. Perturbations of the ₁ and _18a modes have been observed.

We will give an outlook how in the future the rovibrational spectra of larger molecules of biological relevance can be recorded and analysed using the combination of our highly resolving spectrometer with Synchrotron radiation and applying our spectral analysis tools to the complicated spectra.