1 / 24

Microwaves are not just for Cooking!

13879.0. 13879.5. 1. Microwaves are not just for Cooking!. by. Nicholas R. Walker. University of Bristol. 30 th January, 2009. Vibrational Spectroscopy Cause molecules to bend, stretch and twist. Electronic Spectroscopy Movement of electrons between levels. Microwave Spectroscopy

mea
Download Presentation

Microwaves are not just for Cooking!

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. 13879.0 13879.5 1 Microwaves are not just for Cooking! by Nicholas R. Walker University of Bristol 30th January, 2009.

  2. Vibrational Spectroscopy Cause molecules to bend, stretch and twist. Electronic Spectroscopy Movement of electrons between levels Microwave Spectroscopy Cause molecules to rotate about the centre of mass.

  3. Schrodinger Equation predicts Quantization of Energy H = E Lines in absorption and emission spectra provide a means of probing energy levels in atoms and molecules.

  4. Radio and Radar • Light of short wavelength is most directional (less divergent); Where a is the width of the slit, n is an integer and  is the wavelength. • In principle, short wavelengths are better for radar applications (more directional, not refracted by ionosphere). BUT THERE’S A PROBLEM…… • Wavelengths below ~1.25 cm are efficiently absorbed by H2O vapour.

  5. The sweep absorption (CW) experiment

  6. 3 1946 - First high resolution spectroscopic measurements using microwaves (B. Bleaney). 1950 1954 – Invention of the Maser (Gordon, Zeiger and Townes). 1960 1968 – First polyatomic molecule identified in space is NH3. 1970 1980 1990 2000

  7. Radioastronomy The Atacama Large Millimeter Array (ALMA) is an international collaboration between Europe and N. America to build an array of radio telescopes operating at millimeter and submillimeter wavelengths high in the Andes. - dry, clear skies, minimal interference from Earth’s atmosphere. • L.M. Ziurys and co-workers (Uni. Of Arizona) • Millimetre-wave spectroscopy + radioastronomy • Laboratory studies use an oven to generate metal atoms. • Diatomics (metal hydrides, oxides, nitrides), hydroxides, cyanides, methylidines, amides. • NaCN, MgCN, AlF observed in circumstellar envelopes.

  8. The pulsed emission (FT) experiment Computer technology; Efficient vacuum pumps and fast pulsed gas expansion nozzles; Compatible with pulsed lasers

  9. 7 Animation:Prof. Wolfgang Jäger, Dept. of Chemistry, University of Alberta, Edmonton, AB, CANADA, T6G 2G2.

  10. Fourier Transform Microwave Spectroscopy • Involves many microwave components. • Big vacuum chamber to accommodate cavity. • Reliable, high sensitivity, high resolution.

  11. 1981 – cavity FT-MW spectroscopy (Balle and Flygare). Explore intermolecular potentials. Pre-reactive complexes Hydrogen and van der Waals bonding. 3 1946 - First high resolution spectroscopic measurements using microwaves (B. Bleaney). 1950 1954 – Invention of the Maser (Gordon, Zeiger and Townes). 1960 1968 – First polyatomic molecule identified in space is NH3. 1970 1980 1990 2000 2002 – rotational spectra of OCS in He droplets

  12. House of Thomas Jefferson, Monticello Brooks Pate, University of Virginia Matt Muckle, Justin Neill Gordon Brown

  13. Chirped pulse 6.5-18.5 GHz 20 Gs/s Arb. Waveform Generator 3.96 GHz PDRO Scope Trigger Valve/TWTA Trigger 10 MHz Rb oscillator TWT Amplifier 18.99 GHz PDRO 12 GHz oscilloscope (40 Gs/s) Free induction decay (0.5-11.5 GHz) Chirped Pulse FTMW Spectroscopy • A high intensity, chirped microwave pulse rotationally excites molecules. • The free induction decay from the molecular emission is Fourier transformed (can be done in “real” time). • The data are summed to obtain the broadband microwave spectrum. • Instrument is simpler than existing FTMW instruments because the design benefits from latest technology. Microwave Irradiation

  14. Linear molecules (e.g. OCS) • Effectively no moment of inertia about the a axis. • Moments of inertia about b and c axes are equal. • Only one rotational constant is required to fully describe the rotation of the molecule. c b a S C O a • Asymmetric rotors (e.g. H2O) • Three rotational coordinates needed to fully describe the rotational spectrum. • Three distinct rotational constants are defined. • Spectra are more complicated than linear rotors and become increasingly complicated with increasing number of atoms and bonds. c b O H H Knowing the molecular structure requires measurement of rotational constants. If rotational constants can be measured for different isotopologues of the same molecule, structure can be established.

  15. 2 HRot.=B0J(J+1)–DJJ2(J+1)2 • No zero point energy !! • Level spacing increases with J (J’-J” transitions spaced by 2B) To have rotational spectra…. • Molecules must have permanent dipole moment. • For closed-shell linear molecule (in absence of external magnetic field): • Pure rotation : J=1

  16. 1-hexanal 1-heptene • Rotational spectra of small alkanes and alkenes extensively studied by rotational spectroscopy. • As the length of the hydrocarbon chain increases, the spectra become increasingly complex as a consequence of the multitude of different conformers and isotopologues in the molecular beam. • CP-FTMW allows studies of complex spectra owing to increased bandwidth and accurate intensity profiles. • Comparing the conformational properties of 1-hexanal and 1-heptene allows the role of hydrogen bonding involving the terminal oxygen atom to be explored.

  17. 10,000 nozzle pulses (~half an hour)

  18. FWHM = 125 kHz

  19. Assigned ‘a’ and ‘b’ type transitions of conformer 1. 8836 MHz 10386 MHz

  20. Assigned ‘a’ and ‘b’ type transitions of conformer 1. Assigned ‘b’ and ‘c’ type transitions of conformer 3. 8836 MHz 10386 MHz

  21. Six conformers of 1-hexanal assigned and rotational constants determined

  22. The Bristol CP-FTMW Spectrometer Tables September ‘09 December ‘09 Chamber and pump October ‘09 Circuit components December ‘09 Final details January ‘10

  23. Recent Developments in CP-FTMW Spectroscopy Measuring Picosecond Isomerisation Kinetics via Broadband Microwave Spectroscopy – B.C. Dian et al., Science, 320 pp. 924-928, 16th May 2008. Application to detect chemical warfare agents - Int. J. High Speed Electronics and Systems18 31-45 (2008), J.J. Pajski et al. CP-FTMW Spectrometers constructed at U. Pittsburgh, U. North Texas, Purdue International Symposium on Molecular Spectroscopy, Ohio State University, 2008. Stark Effect Measurements (WF12) – L. Alvarez-Valtierra et al. Low Frequency, 2-8 GHz Operation (WF08) – S. T. Shipman et al. Application to Biomolecules (TA01)– R. G. Bird et al. Room temperature, high pressure measurements in a waveguide cell (WF11) – S.T. Shipman et al.

  24. People Bristol Microwavers Anthony Legon Susanna Stephens Victor Mikhailov Felicity Roberts Sophia To University of Virginia Brooks Pate Gordon Brown Justin Neill Stephen Shipman Financial Support

More Related