University of Illinois Urbana-Champaign

Chirped Pulse Microwave Spectroscopy In Pulsed Uniform Supersonic Flows

Abeysekera, Chamara

Content Files
MH09_Abstract.pdf
MH09_Abstract.txt
MH09_Presentation.pptx

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https://hdl.handle.net/2142/51012

Description

Title
Chirped Pulse Microwave Spectroscopy In Pulsed Uniform Supersonic Flows
Author(s)
Abeysekera, Chamara
Contributor(s)
  • Suits, Arthur
  • Sims, Ian
  • Field, Robert W.
  • Park, Barratt
  • Joalland, Baptiste
  • Prozument, Kirill
  • Oldham, James
Issue Date
2014-06-16
Keyword(s)
Mini-symposium: Spectroscopy in Kinetics and Dynamics
Date of Ingest
  • 2014-09-17T16:55:48Z
  • 2015-04-14T18:38:08Z
Abstract
We present preliminary results describing the development of a new instrument that combines two powerful techniques: Chirped Pulse-Fourier Transform MicroWave (CP-FTMW) spectroscopy and pulsed uniform supersonic flows. It promises a nearly universal detection method that can deliver quantitative isomer, conformer, and vibrational level specific detection, characterization of unstable reaction products and intermediates and perform unique spectroscopic, kinetics and dynamics measurements. We have constructed a new high-power K$_a$-band, 26–40 GHz, chirped pulse spectrometer with sub-MHz resolution, analogous to the revolutionary CP-FTMW spectroscopic technique developed in the Pate group at University of Virginia. In order to study smaller molecules, the E-band, 60–90 GHz, CP capability was added to our spectrometer. A novel strategy for generating uniform supersonic flow through a Laval nozzle is introduced. High throughput pulsed piezo-valve is used to produce cold (30 K) uniform flow with large volumes of 150 cm$^3$ and densities of 10$^{14}$ molecules/cm$^{3}$ with modest pumping facilities. The uniform flow conditions for a variety of noble gases extend as far as 20 cm from the Laval nozzle and a single compound turbo-molecular pump maintains the operating pressure. Two competing design considerations are critical to the performance of the system: a low temperature flow is needed to maximize the population difference between rotational levels, and high gas number densities are needed to ensure rapid cooling to achieve the uniform flow conditions. At the same time, collision times shorter than the chirp duration will give inaccurate intensities and reduced signal levels due to collisional dephasing of free induction decay. Details of the instrument and future directions and challenges will be discussed.
Publisher
International Symposium on Molecular Spectroscopy
Type of Resource
text
Genre of Resource
Conference Paper / Presentation
Language
English
Permalink
http://hdl.handle.net/2142/51012
DOI
https://doi.org/10.15278/isms.2014.MH09
Copyright and License Information
Copyright 2014 by the authors. Licensed under a Creative Commons Attribution 4.0 International License. http://creativecommons.org/licenses/by/4.0/

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Abstracts & Presentations - 2014 International Symposium on Molecular Spectroscopy PRIMARY