Directory: Faculty

Michael D. Morse

PHYSICAL CHEMISTRY

Professor

B.S., Haverford College, 1974
Ph.D., University of Chicago, 1980
NSF and Hertz Foundation Postdoctoral Fellow
Postdoctoral Fellow, University of Chicago, 1980-81
Rice University, 1981-1984

Phone: (801) 581-8319

Office: 3428 HEB-S

Email: morse@chem.utah.edu

Research Group

Publications

Activities & Awards

Robert W. Parry Teaching Award, 1991
Fellow, AAAS, 1993
Editorial Board Member, Journal of Chemical Physics, 1997-99
University of Utah Distinguished Research Award, 1997
ASUU Student Choice Award for Excellence in Teaching, 1998
University of Utah Distinguished Teaching Award, 1999
William W. Epstein Outstanding Educator Award, 2001
Fellow, American Physical Society, 2004

Research Interests

Research in Professor Morse’s group is directed toward understanding the chemical bonding and electronic structure in metallic and semiconductor systems by detailed spectroscopic investigations. This research makes extensive use of laser spectroscopy through laser-induced fluorescence, resonant two-photon ionization, and infrared multipass direct absorption techniques. In many of these experiments, metal or semiconductor atoms are ablated from an appropriate target in the throat of a pulsed supersonic expansion by a focused laser pulse. Condensation of the atomic species then occurs in the high pressure region downstream from the point of vaporization. Expansion into vacuum cools the molecules to a few Kelvin, then isolates them from further collisions as the pressure drops. Farther downstream, a variety of spectroscopic experiments are performed, aimed at understanding the molecular structure (both electronic and geometrical) of the small metal molecules.

One spectroscopic technique used is resonant two-photon ionization spectroscopy (R2PI). In this method, a tunable dye laser is scanned in conjunction with a fixed frequency excimer laser. The excimer laser wavelength is chosen so that it cannot ionize the ground state of the molecule with a single photon, but the combination of one dye laser photon plus one excimer laser photon is sufficient for ionization. Under these conditions an enhancement of the ion signal is observed in a mass spectrometer whenever the dye laser is resonant with a molecular absorption. By detecting the ions in a mass spectrometer we can identify the mass of the absorber. In these spectroscopic studies it is possible to measure vibrational frequencies, bond lengths, electronic state symmetries, and bond strengths of many novel species. Among the molecules first studied in our group are Si₂N, MoC, PdC, NbCr, YCu, Ti₂, GaAs, LiCu, AlNi, Au₃, Al₃, Bi₃, and CuAgAu. More recently we have recorded electronic spectra of unsaturated organometallic molecules including CrCH₃, CrCCH, and NiCH₃. These are among the most complex unsaturated transition-metal ligand molecules ever spectroscopically studied in the gas phase.

In a second instrument, a molecular species observed using R2PI is excited and the fluorescence is dispersed to provide information about the vibrational levels of the ground and low-lying electronic states. This instrument employs a sensitive charge-coupled device array detector. We also have the ability to study molecules using a cw ring dye laser, which provides an instrumental resolution of better than 0.003 cm-1. This permits the study of finer details such as hyperfine interactions and electric dipole moments.

Research in the Morse group is also directed toward extending supersonic jet techniques to include other spectroscopies and other types of molecules. In one such extension, we have built a pulsed-discharge slit jet spectrometer that is used with an infrared diode laser to obtain spectra of unsaturated transition metal carbonyls at a resolution of approximately 0.007 cm-1. Other extensions of spectroscopic methods are planned, including use of an ion trap to obtain photodissociation action spectra of molecular cations.

Selected Publications

A. Martinez and M. D. Morse, “Infrared diode laser spectroscopy of jet-cooled NiCO, Ni(CO)₃(¹³CO), and Ni(CO)₃(C¹⁸O),” J. Chem. Phys. 124, 124316 (2006).
G. K. Rothschopf and M. D. Morse, “Monoligated monovalent Ni: the 3d⁹_Ni manifold of states of NiCu and comparison to the 3d⁹ states of AlNi, NiH, NiCl, and NiF,” J. Phys. Chem. A 109, 11358-63 (2005).
S. Shin, D. J. Brugh, and M. D. Morse, “Radiative lifetime of the v=0, 1 levels of the A ⁶Σ⁺ state of CrH,” Astrophys. J. 619, 407-11 (2005).
D. J. Brugh, R. S. DaBell, and M. D. Morse, “Vibronic spectroscopy of unsaturated transition metal complexes: CrC₂H, CrCH₃, and NiCH₃,” J. Chem. Phys. 121, 12379-85 (2004)
J. C. Fabbi, L. Karlsson, J. D. Langenberg, Q. D. Costello, and M. D. Morse, “Dispersed fluorescence spectroscopy of AlNi, NiAu, and PtCu,” J. Chem. Phys. 118, 9247-56 (2003).
N. F. Lindholm, D. J. Brugh, G. K. Rothschopf, S. M. Sickafoose, and M. D. Morse, “Optical spectroscopy of jet-cooled NiSi,” J. Chem. Phys. 118, 2190-6 (2003).
D. J. Brugh and M. D. Morse, “Resonant two-photon ionization spectroscopy of NiC,” J. Chem. Phys. 117, 10703-14 (2002).
M. B. Airola and M. D. Morse, “Rotationally resolved spectroscopy of Pt₂,” J. Chem. Phys. 116, 1313-17 (2002).
S. M. Sickafoose, A. W. Smith, and M. D. Morse, “Optical spectroscopy of tungsten carbide (WC),” J. Chem. Phys. 116, 993-1002 (2002).
S. M. Sickafoose, D. A. Hales, and M. D. Morse, “The near infrared ²π(a_β_J) – X ²σ⁺(b_βS) band systems of TiCo and ZrCo,” Can. J. Phys. 79, 229-45 (2001).
Z.-W. Fu, L. M. Russon, M. D. Morse, and P.B.Armentrout, “Photodissociation measurements of bond dissociation energies: D₀(Al₂-Al), D₀(TiO+-Mn), and D₀(V ₂ ⁺-V),” Int. J. Mass Spectrom. 204, 143-57 (2001).
R. S. DaBell, R. G. Meyer, and M. D. Morse, “Electronic structure of the 4d transition metal carbides: Dispersed fluorescence spectroscopy of MoC, RuC, and PdC,” J. Chem. Phys. 114, 2938-54 (2001).