Frontiers in Spectroscopy
Chemical Physics 880 and 880A
Winter 2006
| Instructor: Terry A. Miller | Phone: 292-2569 |
| Office: 18 Celeste Lab | email: tamiller@chemistry.ohio-state.edu |
Course Description: This course will provide students with an overview of topics on the frontier of spectroscopic research. It will exploit internationally renowned lecturers, as well as outstanding OSU faculty, to cover topics ranging from very fundamental to quite applied. General areas to be covered will include fundamental characteristics of molecular quantum structure, electromagnetics, new experimental techniques, remote sensing, ultra-high sensitivity analytical techniques, astrophysical applications, etc. It is planned that the course will be offered multiple times, with topics and speakers varying with each offering. The lecturers for the upcoming Winter quarter are listed below.
Each topic will be covered by lectures on Wednesday and Friday mornings, 9:00-10:18AM, in MP2015.
Thursdays discussions this year only will begin at 8:45-9:55AM on Thursdays in MP2015.
PLEASE NOTE: Dongping Zhong's lectures Wednesday January 18 and Friday January 20 will begin at 9:30am.
Prerequisites: Chemistry 862 or Physics 828 or permission of the instructor
Required Text: None; suggested articles for reading will be supplied prior to the lecture on a given topic.
A note regarding WebCT: All readings and lecture notes are located on WebCT. If you were enrolled for Frontiers this quarter, you have your normal student login and password. If you are an advisor or post-doc and would like access to the readings and notes, email Becky Gregory, gregory.10@osu.edu, and she will arrange for a login and password for this site.
List of speakers and dates scheduled:
January 11-13 Robert Boyd - University of Rochester
Recommended readings as well as the lecture notes are located on WebCT
Readings: Bentley, Bigelow-Ruby-PRL, Boto-Dowling, Fast=Slow-Bigelow-Science,
Gauthier-Boyd, and GSA-Quantum-Litho
Lecture 2 - Quantum Imaging: Enhanced Image Formation Using Entangled Photons
Image formation making use of quantum states of light allow dramatic new
possibilities in the field of image science. In this contribution, we review
some of the conceptual possibilities afforded by quantum imaging and describe
some recent work that displays some of these features.
January 18-20 Dongping Zhong - The Ohio State University
PLEASE NOTE: Dongping Zhong's lectures Wednesday January 18 and Friday January 20 will begin at 9:30am.
Recommended readings as well as the lecture notes are located on WebCT Readings: AHZ-Chem.Rev.-04 , DZ-CPL-04, DZ-JPCB-05 SA-Chem.Rev.-03 , DZ-JPCB-04, DZ-PNAS-05
Recommended readings as well as the lecture notes are located on WebCT
Readings: M+(L)Ann Rev Phys
Chem, IR-IREV, NJC-Frontiers
Recommended readings as well as the lecture notes are located on WebCT
Lecture 2 - Laser probes of conformational isomerization: Valley-to-valley searches for molecular-scale mountain passes
The single-conformation spectroscopy described in the first lecture provides a foundation for studies of conformational isomerization dynamics following selective excitation of single conformational isomers. These studies utilize a unique ‘hole-filling’ experimental protocol, which will be introduced and described in some detail. Selective excitation of single conformers with well-defined internal energy is followed by collisional cooling and conformation-specific detection. In so doing, one can study isomerization involving specific X→Y reactant-product pairs. In favorable circumstances, conformation-specific product quantum yields can be determined following selective excitation of single conformations in well-defined near-IR and mid-IR fundamentals. When stimulated emission pumping is used as excitation scheme, the energy thresholds for isomerization can be determined, effectively using spectroscopy to measure barrier heights to isomerization. The methods also can be applied to unique kinds of isomerization events, including those in which a single solvent molecule in a solute-solvent complex shuttles between H-bonding sites, swaps positions with another solvent molecule, or isomerizes in competition with solute isomerization.
Recommended readings are located on WebCT
Readings: AO_CRDS,
AOBI, CST_calcrdslif
LP59545
JOSABscan
Ballistic imaging is an optical technique that was originally developed for imaging through tissue. As it turns out, the near field of an atomizing spray (at the tip where it exits) has almost the same optical depth as human tissue, caused by a dense fog of very small droplets. For this reason, spray breakup physics in the near field has been the missing link in a complete description of spray breakup. We have recently demonstrated that transient ballistic imaging using an amplified short pulse laser system can provide images of liquid core breakup in atomizing sprays. This talk will describe the technique, present a few spray results, and discuss potential new directions.
Many forms of absorption spectroscopy have been developed over time, with various levels of sensitivity. One of the advantages of pulsed cavity ringdown spectroscopy is that it can be used with very common pulsed laser systems to achieve very high sensitivity. In this talk, models for the intracavity mode structure will be discussed, together with implications for system stability and design. Several applications will be presented, and then a few other related techniques will be discussed.
Grading: Satisfactory/Unsatisfactory options: Class attendance and participation
Letter grade option: Class attendance and participation plus term paper
(Grades will be assigned solely by OSU faculty.)
04270-7 (3 hours) Call number for ChemPhys 880 (S/U option)
04271-2 (3 hours) Call number for ChemPhys 880A (letter grade option prerequisite=a previous spectroscopy course at OSU in Chemistry or Physics or prior permission of the instructor)