cina

Full Name
Jeffrey Cina
First Name
Jeffrey
Last Name
Cina
Affiliation
Faculty
Title
Professor
Additional Title
Theoretical Physical Chemistry
Phone
541-346-4617
Office
146 Klamath Hall, 1253 University Of Oregon, Eugene OR 97403-1205
Departments
Chemistry and Biochemistry
OMQ
Affiliated Departments
Chemistry and Biochemistry
Physics
Adviser
<em>Not taking PhD students</em>
Profile Section
Education

Jeff Cina Recieved his PhD in Theoretical Chemistry from the University of California, Berkely in 1985. He was a postdoc with professor Robert Silbey and at the James Franck Institute where he went on to become an assistant professor. He joined the faculty of the chemistry department of the University of Oregon.

B.S., University of Wisconsin, Madison, 1979. Ph.D., University of California, Berkeley, 1985 (Robert A. Harris). Postdoctoral: Massachusetts Institute of Technology, 1985–87 (Robert Silbey). Honors and Awards: James Franck Fellow, 1987–88; Camille and Henry Dreyfus Teacher-Scholar, 1991–96; John Simon Guggenheim Memorial Foundation Fellowship, 2003-2004. University of Oregon Fund for Faculty Members Excellence Award, 2008. At Oregon since 1995.

Research

My group works on the theory and simulation of time-resolved optical spectroscopy. Time-resolved optical spectroscopy on the ultrafast (femtosecond) timescale affords a uniquely powerful means to probe in real time — and also to influence — the course of molecular processes in the gases, liquids, solid materials, and biological macromolecules. Progress in this area requires direct collaboration between theoretical and experimental investigators because the systems of interest can be complex — often involving multiple electronic states, induced motion in many interatomic modes, and a complicated interplay between molecular dynamics and optical interactions — and because experimental capabilities are progressing rapidly. Although the signals are rich and informative, they’re challenging to simulate and interpret!

We are helping to develop the basic theory of wave-packet interferometry (WPI) — a form of nonlinear spectroscopy using sequences of ultrashort pulses with specified optical phase relationships — to gain direct experimental information at the level of time-dependent quantum mechanical wave functions (rather than probability densities). Our results indicates that it should be possible to use WPI as a form of analog computation to experimentally determine the evolving nuclear wave function of a polyatomic molecule driven by a short laser pulse of arbitrary temporal shape. Recent simulations of wave-packet reconstruction in the E-state of gas-phase Li2 (in which vibrations and rotations cannot be dynamically separated) demonstrate the capacity of WPI to determine the state of a realistic multi-dimensional quantum mechanical system. Our theoretical work in the area of wave-packet interferometry is taking place in collaboration with experimental groups at Oregon and elsewhere.

infographicof how optical control applies and WPI to electronic energy transfer,

We are also very excited about the prospects for applying optical control and WPI to electronic energy transfer, a key process underlying biochemical energy-generation in photosynthesis and photovoltaic power generation. In addition to completing a comprehensive analysis on the use of WPI with polarized laser pulses to reveal amplitude-level information on the coherent vibrational dynamics accompanying electronic excitation transfer, we are carrying out realistic simulations on various model energy-transfer complexes. Our treatment puts forward an original explanation for the previously puzzling appearance of coordinated vibrational quantum beats in parallel and perpendicular emission channels in time-resolved polarized emission from the bacterial photosynthetic light-harvesting complex LH-1. These findings give strong hints for strategies to control the spatial transport of electronic excitation via external laser control of intra- and inter-chromophore vibrations.

Another area of current activity is in the simulation of condensed phase molecular processes by means of the reduced dynamical descriptions of Redfield theory and other relaxation-theory treatments along with approximate wave packet-based descriptions of lattice-mode dynamics. We have been able to propose, analyze, and simulate in detail a method for distance-sensitive intermolecular communication via coherent lattice waves between different types of molecular “impurities” in cryogenic matrices. The approach envisions the detection of short-pulse electronic excitation of one kind of substitutional impurity by way of time-resolved coherent anti-Stokes Raman scattering (tr-CARS) difference measurements on guest molecules of another type. The predicted difference signals show step-like switching behavior of a kind not usually seen in ultrafast spectroscopy. This work dovetails nicely with ongoing experimental work in the area of matrix-isolation spectroscopy.

Publications

55. Jason D. Biggs and Jeffrey A. Cina, “Using Wave-Packet Interferometry to Monitor the External Vibrational Control of Electronic Excitation Transfer,” under preparation for J. Chem. Phys.

54. Jeffrey A. Cina, “Wave-Packet Interferometry and Molecular State Reconstruction: Spectroscopic Adventures on the Left-Hand Side of the Schrödinger Equation,” Annu. Rev. Phys. Chem. 59, 319-42 (2008); invited review article.

53. Craig T. Chapman and Jeffrey A. Cina, “Semiclassical treatments for small-molecule dynamics in low-temperature crystals using fixed and adiabatic vibrational bases,” J. Chem. Phys. 127, 114502/1-10 (2007).

52. Craig T. Chapman, Jeffrey A. Cina, and Mary A. Rohrdanz, “Intermolecular communication and a vibrationally adiabatic basis treatment of small-molecule dynamics in low temperature solids,” Ultrafast Phenomena XV, R.J. Dwayne Miller, Andrew M. Weiner, Paul Corkum, and David M. Jonas (Eds.)(Springer, Berlin, 2007) pp. 318 – 320.

51. Jeffrey A. Cina, “Bob, so far. A scientific biography of Robert A. Harris,” Molec. Phys. 104, 1145-1159 (2006, not refereed); special number in honor of Robert A. Harris.

50. Travis S. Humble and Jeffrey A. Cina, “Nonlinear wave-packet interferometry and molecular state reconstruction in a vibrating and rotating diatomic molecule,” J. Phys. Chem. B 110, 18879-18892 (2006); Robert J. Silbey Festschrift.

49. M. A. Rohrdanz and J. A. Cina, “Probing intermolecular communication via lattice phonons with time-resolved coherent anti-Stokes Raman scattering,” Molec. Phys. 104, 1161 (2006).

48. Travis S. Humble and Jeffrey A. Cina, “Molecular State Reconstruction by Nonlinear Wave Packet Interferometry,” Ultrafast Phenomena XIV, T. Kobayashi, T. Okada, T. Kobayashi, K.A. Nelson, S. De Silvestri (Eds.) (Springer, Berlin, 2005) p. 514.

47. Mary A. Rohrdanz and Jeffrey A. Cina, “Calculating Ultrafast Nonlinear Optical Signals from Molecules in Cryogenic Matrices,” Ultrafast Phenomena XIV, T. Kobayashi, T. Okada, T. Kobayashi, K.A. Nelson, S. De Silvestri (Eds.) (Springer, Berlin, 2005) p. 523.

46. J.A. Cina and G.R. Fleming, “Vibrational coherence transfer and trapping as sources for long-lived quantum beats in polarized emission from energy transfer complexes,” J. Phys. Chem. A 108, 11196 (2004).

45. J. A. Cina and Travis S. Humble, "Molecular Wavepacket Decomposition by Nonlinear Interferometry," Bull. Chem. Soc. Jpn. 75, 1135 (2002).

44. Travis S. Humble and Jeffrey A. Cina, "Molecular State Reconstruction by Nonlinear Wave Packet Interferometry," Phys. Rev. Lett. 93, 60402 (2004).

43. J. A. Cina, D. Kilin, and T. S. Humble, "Wave packet interferometry for short-time electronic energy transfer: Multidimensional optical spectroscopy in the time domain," J. Chem. Phys. 118, 46 (2003).

42. Dmitri Kilin and J. A. Cina, “Wavepacket Interferometry for Energy Transfer: Ultrafast 2D Electronic Spectroscopy,” in Ultrafast Phenomena 13, R.D. Miller, M.M. Murnane, N.F. Scherer, and A.M. Weiner (Eds.), (Springer Verlag, 2002) page 505.

Additional Publications

41. J. A. Cina and Travis S. Humble, “Molecular Wavepacket Decomposition by Nonlinear Interferometry,” Bull. Chem. Soc. Jpn. 75, 1135 (2002).

40. J. A. Cina, “Molecular Wavepacket Decomposition by Nonlinear Interferometry,” in The Twelfth International Conference on Ultrafast Phenomena, OSA Technical Digest (Optical Society of America, Washington, DC, 2000), pp. 362–364.

39. J. A. Cina, “Nonlinear wavepacket interferometry for polyatomic molecules,” J. Chem. Phys. 113, 9488 (2000).

38. J. A. Cina, “On impulsive excitation of pseudorotation for geometric phase detection”, J. Raman Spectrosc. 31, 95 (2000), invited article for special number on Femtosecond Coherent Raman Spectroscopy.

37. J. A. Cina, "Impulsive Excitation of Pseudo-Rotation for Geometric Phase Detection Revisited", Proceedings of the XIV International Symposium on Electron-Phonon Dynamics and Jahn-Teller Effect (World Scientific, Singapore, 1999).

36. What Can Short-Pulse Pump-Probe Spectroscopy Tell Us About Franck-Condon Dynamics?”, Y.-C. Shen and J. A. Cina, J. Chem. Phys. 110, 9793 (1999).

35. The Relaxation Dynamics and Short-Time Optical Response of a Multi-Mode Open System, L. W. Ungar and J. A. Cina, J. Phys. Chem. A 102, 7382 (1998).

34. Short-Time Fluorescence Stokes Shift Dynamics, L. W. Ungar and J. A. Cina, Adv. Chem. Phys. 100, 171 (1997).

33. Chirped-Pulse Sequences for Impulsive Vibrational Excitation, E. M. Hiller and J. A. Cina, Proceedings of the Fifteenth International Conference on Raman Spectroscopy, S. A. Asher and P. B. Stein, Eds. (Wiley, 1996) p. 62.

32. Optimal Sequences for Chirped-Pulse-Stimulated Vibrational Motion, E. M. Hiller and J. A. Cina, Ultrafast Phenomena X, P. F. Barbara, J. G. Fujimoto, W. H. Knox, and W. Zinth, Eds. (Springer, 1996) p. 221.

31. Can Chirp Enhance Cumulative Pre-resonant Impulsive stimulated Raman Excitation? E. M. Hiller and J. A. Cina, J. Chem. Phys. 105, 3419 (1996).

30. Toward Preresonant Impulsive Raman Preparation of Large Amplitude Vibrational Motion, T. J. Smith and J. A. Cina, J. Chem. Phys. 104, 1272 (1996).

29. Electric Field Optical Activity, Rayleigh Optical Activity, and the Measurement of Superpositions of Chiral Amplitudes, R. A. Harris and J. A. Cina, Faraday Discuss. 99, 369 (1994).

28. Superpositions of Handed Wave Functions, J. A. Cina and R. A. Harris, Science 267, 832 (1995), invited Perspectives article.

27. Theoretical Studies of Time-Resolved Fluorescence Anisotropy from Coupled Chromophore Pairs; A. Matro and J. A. Cina, J. Phys. Chem. 99, 2568 (1995) (Stuart A. Rice Festschrift).

26. Use of Phase-Locked Pulse Sequences for Probing the Degradation of Chiral Coherences; J. A. Cina and R. A. Harris, Ultrafast Phenomena IX, W. Knox and P. Barbara, Eds. (Springer-Verlag, 1994) p. 486.

25. Time-Resolved Fluorescence Anisotropy in Chromophore Pairs; A. Matro and J. A. Cina, Ultrafast Phenomena IX, W. Knox and P. Barbara, Eds. (Springer-Verlag, 1994) p. 460.

24. On the Measurement of Superpositions of Chiral Amplitudes by Polarized Light Scattering; R. A. Harris, Y. Shi and J. A. Cina, J. Chem. Phys. 101, 3459 (1994).

23. Aspects of Impulsive Stimulated Scattering in Molecular Systems; Victor Romero-Rochin and Jeffrey A. Cina, Phys. Rev. A 50, 763 (1994).

22. Superpositions of Chiral Amplitudes; J. A. Cina and R. A. Harris, Laser Techniques for State Selected and State-to-State Chemistry II, SPIE Proceedings 2124, 244 (1994).

21. On the Preparation and Measurement of Superpositions of Chiral Amplitudes; J. A. Cina and R. A. Harris, J. Chem. Phys. 100, 2531 (1994).

20. Short Time Semiclassical Dynamics of Optical Processes in Condensed Phases; L. W. Ungar and J. A. Cina, J. Lumin. 58, 89 (1994).

19. Resonant Short-Pulse Effects on Nuclear Motion in the Electronic Ground State; T. J. Smith, L. W. Ungar, and J. A. Cina, J. Lumin. 58, 66 (1994).

18. Impulsive Effects of Phase-Locked Pulse Pairs on Nuclear Motion in the Electronic Ground State; J. A. Cina and T. J. Smith, J. Chem. Phys. 98, 9211 (1993).

17. Time-Resolved Optical Tests for Electronic Geometric Phase Development; Jeffrey A. Cina, Timothy J. Smith, Jr., and Victor Romero-Rochin, Advances in Chemical Physics, 83, 1 (1993).

16. Use of Piecewise Phase-Swept Pulses to Counteract Inhomogeneous Broadening in Wave Packet Interferometry; L.W. Ungar, A. Matro and J.A. Cina, Ultrafast Phenomena VIII, J.-L. Martin, A. Migus, G. A. Mourou and A. H. Zewail, Eds. (1993) p. 105.

15. Wave Packet Interferometry and Other Applications of Phase Locked Femtosecond Pulses; G.R. Fleming, N.F. Scherer, M. Cho, A. Matro and J.A. Cina, Ultrafast Phenomena VIII, J.-L. Martin, A. Migus, G. A. Mourou and A. H. Zewail, Eds. (1993) p. 99.

14. Fluorescence-Detected Wave Packet Interferometry II: Role of Rotations and Determination of the Susceptibility; N. F. Scherer, A. Matro, R. J. Carlson, M. Du, L. D. Ziegler, J. A. Cina and G. R. Fleming, J.Chem. Phys. 96, 4180 (1992).

13. Fluorescence-Detected Wave Packet Interferometry: Time Resolved Molecular Spectroscopy with Sequences of Femtosecond Phase-Locked Pulses; N. F. Scherer, R. Carlson, A. Matro, M. Du, A. J. Ruggiero, V. Romero-Rochin, J. A. Cina, G. R. Fleming and S. A. Rice, J. Chem. Phys. 95, 1487 (1991).

12. Phase-Controlled Optical Pulses and the Adiabatic Electronic Sign Change, J. A. Cina, Phys. Rev. Lett. 66, 1146 (1991).

11. Optical Impulsive Excitation of Molecular Pseudorotation in Jahn-Teller Systems; J. A. Cina and V. Romero-Rochin, J. Chem. Phys. 93, 3844 (1990).

10. Time Development of Geometric Phases in the Longuet-Higgins Model; V. Romero-Rochin and J. A. Cina, J. Chem. Phys. 91, 6103 (1989).

9. Molecular Excitations and the Quantum Adiabatic Phase for a Nuclear Spin; S. A. Schofield and J.A. Cina, Molec. Phys. 67, 271 (1989).

8. Polaron Formation in the Acoustic Chain; D.W. Brown, K. Lindenberg, B.J. West, J.A. Cina, and R. Silbey, J. Chem. Phys. 87, 6700 (1987).

7. Classical Adiabatic Angle and Geometrical Phase in Spin Precession; J.A. Cina, Chem. Phys. Lett. 132, 393 (1986).

6. Optical Hartmann-Hahn Resonance and the Spatial Correlation of Inhomogeneous Broadening in Molecular Solids; J.A. Cina and R. Silbey, J. Chem. Phys. 85, 2450 (1986).

5. A Simple Electron Gas Treatment of the Magnetic Susceptibility Tensor of the Lowest State of H2; J.A. Cina and R.A. Harris, J. Chem. Phys. 82, 5018 (1985).

4. An Electron Gas Treatment of the Potential Curve and Polarizability Tensor of the Lowest State of H2; J.A. Cina and R.A. Harris, J. Chem. Phys. 80, 329 (1984).

3. Thomas-Fermi Theory in a Weak, Slowly Varying Vector Potential; R.A. Harris and J.A. Cina, J. Chem. Phys. 79, 1381 (1983).

2. Use of Difference Boundary Sedimentation Velocity to Investigate Nonspecific Protein-Nucleic Acid Interactions; T.M. Lohman, C.G. Wensley, J. Cina, R.R. Burgess, and M.T. Record, Jr., Biochemistry 19, 3516 (1980).

1. Minor Alkaloids of Camptotheca acuminata; J.A. Adamovics, J.A. Cina, and C.R. Hutchinson, Phytochemistry 18, 1085 (1979).

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