1990 - Fellow of American Physical Society (APS) Citation For his development and application of the optothermal detection method in the elucidation of the structure and dynamics of loosely bound molecular complexes
1987 - Fellow of Alfred P. Sloan Foundation
Roger E. Miller mostly deals with Atomic physics, Infrared spectroscopy, Molecule, Analytical chemistry and Infrared. His Atomic physics study focuses on Excited state in particular. Within one scientific family, Roger E. Miller focuses on topics pertaining to Molecular physics under Infrared spectroscopy, and may sometimes address concerns connected to Computational chemistry.
His work carried out in the field of Molecule brings together such families of science as Chemical physics and Helium, Liquid helium. The Analytical chemistry study combines topics in areas such as Laser and Aerosol. His Infrared study which covers Spectrometer that intersects with Fermi resonance, Near-infrared spectroscopy, Two-dimensional infrared spectroscopy and Infrared spectroscopy correlation table.
The scientist’s investigation covers issues in Infrared spectroscopy, Atomic physics, Infrared, Helium and Analytical chemistry. His Infrared spectroscopy study integrates concerns from other disciplines, such as Rotational spectroscopy, Molecule, Ab initio quantum chemistry methods, Intermolecular force and Molecular physics. His Atomic physics research is multidisciplinary, incorporating elements of Chemical physics and van der Waals force.
His Infrared research includes elements of Spectrometer, Molecular beam, Diatomic molecule and Acetylene. Roger E. Miller has included themes like Far-infrared laser, Physical chemistry, Chemical polarity and Transition dipole moment in his Helium study. His Analytical chemistry study combines topics in areas such as Ionic bonding, Hydrogen fluoride, Laser and Aerosol.
His primary scientific interests are in Atomic physics, Helium, Superfluid helium-4, Transition dipole moment and Infrared spectroscopy. His studies deal with areas such as Chemical physics, van der Waals force, Infrared and Ab initio quantum chemistry methods as well as Atomic physics. His studies in Helium integrate themes in fields like Chemical engineering, Engineering physics and Chemical polarity.
His research integrates issues of Imidazole, Photochemistry, Molecular physics, Molecular vibration and Density functional theory in his study of Transition dipole moment. His Infrared spectroscopy research incorporates elements of Dipole, Atom, Solvation and Intermolecular force. Intermolecular force is closely attributed to Analytical chemistry in his research.
Atomic physics, Helium, Infrared spectroscopy, Solvation and Infrared are his primary areas of study. His Helium research integrates issues from Chemical physics, Fragmentation and van der Waals force. He has researched Chemical physics in several fields, including Mass spectrum, Mass spectrometry and Electron ionization, Ionization, Chemical ionization.
His study focuses on the intersection of Infrared spectroscopy and fields such as Computational chemistry with connections in the field of Molecular physics and Ab initio quantum chemistry methods. Roger E. Miller interconnects Rotational spectroscopy, Methyl radical and Electric dipole moment in the investigation of issues within Solvation. His Infrared research includes themes of Water cluster, Ring and Cluster.
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Infrared spectroscopy of helium nanodroplets: novel methods for physics and chemistry
M. Y. Choi;G. E. Douberly;T. M. Falconer;W. K. Lewis.
International Reviews in Physical Chemistry (2006)
High‐resolution near‐infrared spectroscopy of water dimer
Z. S. Huang;R. E. Miller.
Journal of Chemical Physics (1989)
Reactive Uptake of Ozone by Oleic Acid Aerosol Particles: Application of Single-Particle Mass Spectrometry to Heterogeneous Reaction Kinetics
Geoffrey D. Smith;Ephraim Woods;Cindy L. Deforest;Tomas Baer.
Journal of Physical Chemistry A (2002)
Vibrational transition moment angles in isolated biomolecules: a structural tool.
F. Dong;R. E. Miller.
Structure and vibrational dynamics of the CO2 dimer from the sub‐Doppler infrared spectrum of the 2.7 μm Fermi diad
K. W. Jucks;Z. S. Huang;R. E. Miller;G. T. Fraser.
Journal of Chemical Physics (1988)
The structure of the carbon dioxide dimer from near infrared spectroscopy
K. W. Jucks;Z. S. Huang;D. Dayton;R. E. Miller.
Journal of Chemical Physics (1987)
Molecular clusters: Structure and dynamics of weakly bound systems
Zlatko Bačić;Roger E. Miller.
The Journal of Physical Chemistry (1996)
Initial state effects in the vibrational predissociation of hydrogen fluoride dimer
E. J. Bohac;Mark D. Marshall;R. E. Miller.
Journal of Chemical Physics (1992)
Four Tautomers of Isolated Guanine from Infrared Laser Spectroscopy in Helium Nanodroplets
Myong Yong Choi;Roger E. Miller.
Journal of the American Chemical Society (2006)
Spectroscopy of pendular states: The use of molecular complexes in achieving orientation.
Block Pa;Bohac Ej;Miller Re.
Physical Review Letters (1992)
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