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135. Bingwei Xu, Yves Coello, Giovana T. Nogueira, Flavio C. Cruz, and Marcos Dantus "Asynchronous encrypted information transmission with sub-6 fs laser system at 2.12 GHz repetition rate" Optics Express, Vol. 16, Issue 19, pp. 15109-15114 
134. Giovana T. Nogueira, Bingwei Xu, Yves Coello, Marcos Dantus, and Flavio C. Cruz " Broadband 2.12 GHz Ti:sapphire laser compressed to 5.9 femtoseconds using MIIPS" Optics Express, Vol. 16, Issue 14, pp. 10033-10038
133. Jess M. Gunn, Scott H. High, and Marcos Dantus. "Measurement of Dispersion Properties of Silver Nanowires Used as Plasmon Waveguides", Ultrafast Phenomena XVI, Stresa, Italy (2008)
132. Vadim V. Lozovoy, Yair Andegeko,
Xin Zhu, Marcos Dantus, “Applications of ultrashort shaped pulses
in microscopy and for controlling chemical reactions,” Chemical
Physics, doi:10.1016/j.chemphys.2008.01.025 (2008).
131. Marcos Dantus, Haowen Li, D. Ahmasi
Harris, Bingwei Xu, Paul J. Wrzesinski, and Vadim V. Lozovoy,
“Detection of chemicals at a standoff >10 m distance based on
single-beam coherent anti-Stokes Raman scattering,” Proc. SPIE
6954, 69540P (2008).
130. Marcos Dantus, Vadim V. Lozovoy,
Xin Zhu, and Tissa Gunaratne, “Multidimensional molecular
identification by laser control mass spectrometry,” Proc. SPIE
6954, 69540D (2008).
129. Peng Xi, Lindsay R. Weisel, Yair
Andegeko, Vadim V. Lovozoy, and Marcos Dantus, “Two-photon laser
scanning microscopy with ultrabroad bandwidth 110 nm FWHM femtosecond
pulses,” Proc. SPIE 6860, 68601U (2008).
128. Lindsay R. Weisel, Peng Xi, Yair
Andegeko, Vadim V. Lovozoy, and Marcos Dantus, “Greater signal
and contrast in two-photon microscopy with ultrashort pulses,”
Proc. SPIE 6860, 68601O (2008).
127. Marcos Dantus, Dmitry Pestov and
Yair Andegeko, “Nonlinear optical imaging with sub-10 fs
pulses,” Book Chapter on Nonlinear Optical Imaging (2008).
126. Marcos Dantus and Yair Andegeko,
“Realization of biomedical imaging with ultrashort laser pulses
made possible by automated elimination of chromatic dispersion,”
Submitted to Photonic Tech Briefs (2008).
125. Giovana T. Nogueira, Flavio C. Cruz, Bingwei Xu, Yves Coello, Marcos Dantu, “Broadband 2 GHz Ti:sapphire laser compressed to 5.9 femtoseconds using MIIPS,” Submitted to Optics Express (2008).
124. Peng Xi, Vadim V. Lozovoy, Marcos Dantus, “Multiphoton laser scanning microscope design for 10 femtosecond pulse through dispersion compensation,” Submitted to Journal of Biomedical Optics (2008)
123. Vadim V. Lozovoy, Bingwei Xu, Yves
Coello, and Marcos Dantus, "Direct measurement of spectral phase for
ultrashort laser pulses,” Optics Express 16, 592-597 (2008).
122. Y. Coello, V. V. Lozovoy, T. C. Gunaratne, B. Xu, I. Borukhovich, C. -h. Tseng, T. Weinacht, and M. Dantus, "Interference without an interferometer: a different approach to measuring, compressing, and shaping ultrashort laser pulses," J. Opt. Soc. Am. B 25, A140-A150 (2008)
121. C. Hartmann-Thompson, D. L. Keeley, K. M. Pollock, P. R. Dvornic,
S. E. Keinath, M. Dantus, T.Gunaratne, and D. J. LeCaptain, "One-
and Two-photon Fluorescent Polyhedral Oligosilsesquioxane (POSS)
Nanosensor Arrays for the Remote Detection of Analytes in Clouds, in
Solution and on Surfaces," Submitted to Chemistry of Materials (2007).
120. Y. Coello, B. Xu, T. L. Miller, V.
V. Lozovoy, and M. Dantus, "Group-velocity dispersion measurements of
water, seawater, and ocular components using multiphoton intrapulse
interference phase scan (MIIPS)" Appl. Opt. 46, 8394 (2007).
119. H. Li, A. D. Harris, B. Xu, P. Wrzesisnki, V. V. Lozovoy, M. Dantus “Detection of chemicals at a standoff >10 m distance based on single-beam coherent anti-Stokes Raman scattering,” Optics Express 16, 5499-5504 (2008).
118. P. Xi, Y. Andegeko, L. R. Weisel, V. V. Lozovoy, M. Dantus, “Greater Signal and Less Photobleaching in Two-Photon Microscopy with Ultrabroad Bandwidth Femtosecond Pulses,” Opt. Commun. 281, 1841-1849 (2008)
116. M. Dantus, V.V. Lozovoy, and I.
Pastirk, "MIIPS characterizes and corrects femtosecond pulses," Laser
Focus World 43, 101-104 Feature Article, (2007).
115. I. Pastirk, M. Dantus, “Multidimensional identification of chemical warfare agents using shaped femtosecond pulses,” International Journal of High Speed Electronics and Systems, 18, 63-70 (2008).
114. B. W. Xu, Y. Coello,
V. V. Lozovoy, D. A. Harris, and M. Dantus, "Pulse shaping of octave spanning
femtosecond laser pulses," Optics Express 14, 10939-10944 (2006).
113. D. A. Harris, J. C.
Shane, V. V. Lozovoy, and M. Dantus, "Automated phase characterization and
adaptive pulse compression using Multiphoton Intrapulse Interference Phase
Scan in air,” Optics Express, 15, 1932-1938 (2007).
112.
T. C. Gunaratne, X. Zhu, V. V. Lozovoy, and M. Dantus. “Symmetry
of nonlinear optical response to time inversion of shaped femtosecond
pulses as a clock of ultrafast dynamics,” Chem. Phys. 338, 259-267 (2007). Special Issue on Molecular Wave Packet Dynamics.
111. I. Pastirk, V. V. Lozovoy, and M. Dantus
“Femtosecond pulse shaping adds a new dimension to mass spectrometry,” Applied
Optics, in press (2007).
110.
X. Zhu, T. C. Gunaratne, V. V. Lozovoy and M. Dantus, "In-situ
femtosecond laser pulse characterization and compression during
micromachining," Opt. Express 15, 16061 (2007)
109. J. M. Dela Cruz, V. V. Lozovoy, and M.
Dantus, “Isomeric identification by laser control mass spectrometry,” Journal
of Mass Spectrometry 42 178-186 (2006).
108. M. Ewald, J. M.
Gunn, M. Dantus, “Two-photon induced emission from silver nanoparticle
aggregates on thin films and in solution,” Microscopy and Microanalysis, 12
632-633, (2006).
107. J. M. Gunn, M. Ewald,
M. Dantus, "Remote two-photon emission from dendritic silver nanoclusters,"
Microscopy and Microanalysis 12, 630-631 (2006).
106. J. M. Gunn, M. Ewald,
and M. Dantus, "Polarization and phase control of remote surface-plasmon-mediated
two-photon-induced emission and waveguiding," Nano Letters 6, 2804-2809
(2006).
105. L. Schelhas, J. C.
Shane, M. Dantus, "Selective two-photon imaging of a biological sample,"
Ultrafast Phenomena XV, P. Corkum, D. Jonas, D. Miller, A. M. Weiner Eds.
Springer-Verlag, Berlin (2007).
104. J. M. Gunn, M. Ewald,
M. Dantus, "Properties of two-photon induced emission from dendritic silver
nanoparticles," Ultrafast Phenomena XV, P. Corkum, D. Jonas, D. Miller, A. M.
Weiner Eds. Springer-Verlag, Berlin (2007).
103. V. V. Lozovoy, M. J.
Kangas, T. C. Gunaratne, J. C. Shane, M. Dantus, "Control of molecular
fragmentation using binary phase shaped femtosecond laser pulses," Ultrafast
Phenomena XV, P. Corkum, D. Jonas, D. Miller, A. M. Weiner Eds. Springer-Verlag,
Berlin (2007)
102. B. Xu, Y. Coello,
D. A. Harris, V. V. Lozovoy, M. Dantus, "Amplitude and phase shaping of
ultra-broad-bandwidth femtosecond laser pulses," Ultrafast Phenomena XV, P.
Corkum, D. Jonas, D. Miller, A. M. Weiner Eds. Springer-Verlag, Berlin (2007).
101. V. V. Lozovoy, T. Gunaratne, J. C. Shane, M. Dantus, “Control of chemical
reactions using binary phase shaped femtosecond laser pulses,” ChemPhysChem, 7, 2471-2473 (2006).
100.
V. V. Lozovoy, X.
Zhu, T. C. Gunaratne, D. A. Harris, J. C. Shane, M. Dantus, “Control of
molecular fragmentation using binary phase-shaped femtosecond laser pulses,”
Journal of Physical Chemistry A. 112, 3789-3812 (2007)
99. J. C. Shane, V. V. Lozovoy, and M. Dantus,
"Search space mapping: Getting a picture of coherent laser control," Journal
of Physical Chemistry A 110, 11388-11391 (2006).
98. L. Schelhas, J. C.
Shane, M. Dantus, “Advantages of ultrashort phase-shaped pulses for selective
two-photon activation and biomedical imaging,” Nanomedicine: Nanotechnology,
Biology, and Medicine 2, 177-181 (2006).
97. I. Pastirk, B. Resan, A. Fry, J. MacKay,
and M. Dantus, "No loss spectral phase correction and arbitrary phase shaping
of regeneratively amplified femtosecond pulses using MIIPS," Optics Express
14, 9537-9543 (2006).
96. I. Pastirk, X. Zhu, R. M. Martin, and M.
Dantus, "Remote characterization and dispersion compensation of amplified
shaped femtosecond pulses using MIIPS," Optics Express 14, 8885-8889
(2006).
95.
J.M. Dela Cruz, M. Kangas, I. Pastirk, V.V. Lozovoy and M. Dantus, "Systematic
chemical recognition using shaped laser pulses," Journal of Modern Optics
53, 2533 (2006).
94. V. V. Lozovoy and M.
Dantus, Laser control of Physicochemical Processes; Experiments and
Applications, Annu. Rep. Prog. Chem., Sect. C: Phys. Chem., 102,
227-258, (2006).
93. J. M. Dela Cruz, V. V. Lozovoy, and M.
Dantus, "Coherent control improves biomedical imaging with ultrashort shaped
pulses," Journal of Photochemistry and Photobiology A-Chemistry 180,
307-313 (2006).
92. M. Dantus V. V. Lozovoy, I. Pastirk, J.M. Dela Cruz, "Converting Concepts and Dreams of Coherent Control into Applications." Femtochemistry VII, W. Castelman Ed. Elsevier 434-440 (2006).
91. J. M.Gunn, B. Xu, J.
M. Dela Cruz, V. V. Lozovoy, M. Dantus, "Quantitative phase characterization
and compensation by multiphoton intrapulse interference phase scan (MIIPS)."
Femtochemistry VII, W. Castelman Ed. Elsevier, 526-529 (2006).
90.
J. M.Gunn, B. Xu, J. M. Dela Cruz, V. V. Lozovoy, M. Dantus, "The MIIPS method
for simultaneous phase measurement and compensation of femtosecond laser
pulses and its role in two-photon microscopy and imaging." Proc. SPIE 6108,
61-68, Commercial and Biomedical Applications of Ultrafast Lasers VI; Joseph
Neev, Stefan Nolte, Alexander Heisterkamp, Christopher B. Schaffer; Eds.
(2006).
89.V. V. Lozovoy, B. W. Xu, J. C. Shane, and
M. Dantus, "Selective nonlinear optical excitation with pulses shaped by
pseudorandom Galois fields," Physical Review A 74, 041805(R) (2006).
88. J. C. Shane, V.V. Lozovoy, and M. Dantus, “Search Space Mapping: getting a picture of coherent
laser control,” J. Phys. Chem. A 110, 11388-11391 (2006).
87.
T. Gunaratne, M. Kangas, S. Singh, A. Gross, and M. Dantus, "Influence of
bandwidth and phase shaping on laser induced breakdown spectroscopy with
ultrashort laser pulses," Chemical Physics Letters 423, 197-201 (2006).
86.
B. Xu, J. M. Gunn, J. M. Dela Cruz, V. V. Lozovoy, M. Dantus, “Quantitative
investigation of the MIIPS method for phase measurement and compensation of
femtosecond laser pulses,” J. Optical Society B 23, 750-759 (2006).
85. V. V. Lozovoy, J. C.
Shane, B. W. Xu, and M. Dantus, "Spectral phase optimization of femtosecond
laser pulses for narrow-band, low-background nonlinear spectroscopy," Optics
Express 13, 10882-10887 (2005).
84. J. M. Dela Cruz, V.
V. Lozovoy and M. Dantus, “Quantitative mass spectrometric identification of
isomers applying coherent laser control,” J. Phys. Chem. A 109,
8447-8450 (2005).
83. V. V. Lozovoy and M.
Dantus, “Coherent control in femtochemistry,” ChemPhysChem. 6,
1970-2000 (2005).
82. I. Pastirk, M.
Kangas, and M. Dantus, "Multidimensional analytical method based on binary
phase shaping of femtosecond pulses." J. Phys. Chem. A 109, 2413-2416
(2005).
81. M. Dantus and A. Zewail, "Introduction: Femtochemistry," Chemical Reviews 104, 1717-1718 (2004).
80.
J. M. Dela Cruz, I. Pastirk, M. Comstock, V. V. Lozovoy, and M. Dantus, "Use
of coherent control methods through scattering biological tissue to achieve
functional imaging," Proceedings of the National Academy of Sciences of the
United States of America 101, 16996-17001 (2004).
79.
J. M. Dela Cruz, I. Pastirk, M. Comstock, and M. Dantus, "Coherent control
through scattering tissue, Multiphoton Intrapulse Interference 8." Optics
Express 12, 4144 (2004).
78. M. Comstock, V. V. Lozovoy, I. Pastirk, and M. Dantus, "Multiphoton intrapulse interference 6;
binary phase shaping." Optics Express 12, 1061-1066 (2004).
77. M. Dantus and V.V.
Lozovoy, "Experimental Coherent Laser Control of Physicochemical Processes."
Chem. Reviews 104, 1813-1860 (2004). Special Issue on Femtochemistry,
A. H. Zewail and M. Dantus guest editors.
76. V.V. Lozovoy, M. Comstock, I. Pastirk, and M. Dantus, “Femtosecond Photon Echo Measurements of Electronic Coherence Relaxation of I2 in the presence of He, Ar, N2, O2, C3H8,” Ultrafast Molecular Events in Chemistry and Biology, M. M. Martin and J.T. Hynes Eds. Elsevier, 33 (2004).
75. J. Dela Cruz, I. Pastirk, V.V. Lozovoy, K.A. Walowicz, and M. Dantus, “Control of nonlinear optical excitation with multiphoton intrapulse interference,” Ultrafast Molecular Events in Chemistry and Biology, M. M. Martin and J.T. Hynes Eds. Elsevier, 95 (2004).
74. M. Dantus, V. V. Lozovoy, and I. Pastirk, "Measurement and Repair: The femtosecond Wheatstone Bridge." OE Magazine, 9 (2003).
73. V. V. Lozovoy, I.
Pastirk, and M. Dantus, "Multiphoton intrapulse interference 4;
Characterization and compensation of the spectral phase of ultrashort laser
pulses." Optics Letters 29, 775-777 (2004).
72. M. Dantus and P.
Gross, “Ultrafast Spectroscopy.” Encyclopedia of Applied Physics, American
Institute of Physics , Wiley-VCH, Berlin (2003).
71. M. Dantus and E. J. Brown, “Femtosecond chemical dynamics: gas-phase.” Encyclopedia of Modern Optics , Elsevier, Oxford (2004).
70.
I. Pastirk, J. M. Dela Cruz, K. A. Walowicz, V. V. Lozovoy, and M. Dantus,
"Selective two-photon microscopy with shaped femtosecond pulses ." Optics
Express 11, 1695-1701 (2003).
69. J. M. Dela Cruz, I.
Pastirk, V. V. Lozovoy, K. A. Walowicz, and M. Dantus, "Multiphoton Intrapulse
Interference 3: probing microscopic chemical environments." J. Phys. Chem.
108, 53 – 58 (2003). Our results are featured in the cover.
68. M. Comstock, V. Senekerimyan, and M. Dantus, "Ultrafast Laser Induced
Molecular Alignment and Deformation: Experimental evidence from neutral
molecules and from fragment ions." J. Phys. Chem. 107, 8271 (2003).
Albrecht Special Issue
67.
M. Comstock, V. V. Lozovoy, and M. Dantus,
"Rotational Wavepacket Revivals for Phase Modulation of Ultrafast Pulses."
Chem. Phys. Letters 372, 739-744 (2003).
66. V. V. Lozovoy, I.
Pastirk, K. A. Walowicz, and M. Dantus, “Multiphoton intrapulse interference
II. Control of two- and three-photon laser induced fluorescence with shaped
pulses.” J. Chem. Phys. 118, 3187-3196 (2003).
65. V. V. Lozovoy, I. Pastirk, M. Comstock, K. A. Walowicz, and M. Dantus, “Femtosecond four-wave mixing for molecule based computation,” Ultrafast Phenomena XIII , Heidelberg, Berlin, 97 (2003).
64. M. Comstock, V. V. Lozovoy and M. Dantus, “Femtosecond photon echo measurements of electronic
coherence relaxation between the X(1Σg+) and B(3Π0u+)
states of I2 in the presence of He, Ar, N2, O2, C3H8.”
J. Chem. Phys. 119, 6546-6553 (2003).
63. K. A. Walowicz, I.
Pastirk, V. V. Lozovoy, and M. Dantus, “Multiphoton intrapulse interference 1;
Control of multiphoton processes in condensed phases.” J. Phys. Chem. 106,
9369-9373, (2002). Our results are featured on the cover.
62. V. V. Lozovoy and M.
Dantus, “Photon echo pulse sequences with femtosecond shaped laser pulses as a
vehicle for molecule-based quantum computation.” Chem. Phys. Letters 351,
213-221 (2002).
61. I. Pastirk, M.
Comstock, and M. Dantus, “Femtosecond ground state dynamics of N2O4 and NO2
investigated by degenerate four-wave mixing.” Chem. Phys. Letters 349,
71-78 (2001).
60.
E. J. Brown, I. Pastirk and M. Dantus, “Ultrafast Rotational Anisotropy
Measurements: Nonlinear Saturation Effects." J. Phys. Chem. A 105,
8004-8010 (2001).
59. I. Grimberg, V. V.
Lozovoy, M. Dantus and S. Mukamel, “Femtosecond three-pulse spectroscopies in
the gas phase: density matrix representation.” J. Phys. Chem. A 106,
697-718 (2002). Our results are featured on the cover.
58. V. V. Lozovoy, M. Comstock and M. Dantus, “Four-Wave Mixing and Coherent Control.” in Laser Control and Manipulation of Molecules , A.D. Bandrauk, Y. Fujimura and R.J. Gordon, ACS Publishing, 61 (2002).
57. M. Dantus, “Coherent
nonlinear spectroscopy: From femtosecond dynamics to control,” Annu. Rev.
Phys. Chem. 52, 639 (2001).
56. M. Dantus, "Laser control of chemical
reactions," Chemical & Engineering News 79, 191-191 (2001).
55
. V. Lozovoy, Igor Pastirk,
Matthew G. Comstock, and M. Dantus, “Cascaded Free-Induction Decay
Four-Wave-Mixing.” Chem. Phys. 266, 205-212 (2001). Special
issue on multidimensional spectroscopies.
54.
I. Pastirk, V. V. Lozovoy, and M. Dantus, "Femtosecond
photon echo and virtual echo measurements of the vibronic and vibrational
coherence relaxation times of iodine vapor," Chemical Physics Letters 333,
76-82 (2001).
53. I. Pastirk, M. Comstock, K. A. Walowicz,
V. V. Lozovoy, and M. Dantus, "2D (time-frequency) femtosecond four-wave
mixing at 1014 W/cm2: Molecular and electronic response." Symposium on Optical
Pulse and Beam Propagation III , Photonics West (2001).
52. V. V. Lozovoy, I. Pastirk, E. J. Brown, B.
I. Grimberg, and M. Dantus, "The role of pulse sequences in controlling
ultrafast intramolecular dynamics with four-wave mixing," International
Reviews in Physical Chemistry 19, 531-552 (2000).
51. M. Dantus, “Ultrafast probing and control
of molecular dynamics: Beyond the pump-probe method.” in Femtochemistry , De
Schryver, De Feyter, Schweitzer Eds. Wiley-VCH, 169 (2000).
50. M. Comstock, I. Pastirk, and M. Dantus,
“Ultrafast transient-grating study of molecules after high intensity
excitation.” in Ultrafast Phenomena XII , edited by T. Elsaesser, S. Mukamel,
M. M. Murnane, and N. F. Scherer, 317-319 (2000).
49. V.V. Lozovoy, B. I.
Grimberg, I. Pastirk and M. Dantus, “The role of microscopic and macroscopic
coherence in laser control.” Chem. Phys. 267, 9 (2001). Special
issue on Laser Control of Quantum Dynamics.
48. V. V. Lozovoy, B. I. Grimberg, I. Pastirk,
and M. Dantus, "The role of microscopic and macroscopic coherence in laser
control," Chemical Physics 267, 99-114 (2001).
47. V.V. Lozovoy, E. J. Brown, I. Pastirk, B.
I. Grimberg and M. Dantus, “What role can four-wave mixing techniques play in
coherent control?” Advances in Multiphoton Processes and Spectroscopy 14; and
Quantum control of molecular reaction dynamics , edited by R. J. Gordon and Y.
Fujimura, World Scientific, Singapore, 62-79 (2000).
46. M. Dantus, “The scientific contributions
of A. H. Zewail, Nobel Laureate” European Association Newsletter 69, 7
(2000).
45. U. Marvet, E.J. Brown, and M. Dantus,
“Femtosecond concerted elimination of halogen molecules from halogenated
alkanes.” Phys. Chem. Chem. Phys. 2, 885-891 (2000). Roger
Grice special issue.
44.
V. V. Lozovoy, B. I. Grimberg, E. J. Brown, I.
Pastirk, and M. Dantus, "Femtosecond spectrally dispersed three-pulse
four-wave mixing: the role of sequence and chirp in controlling intramolecular
dynamics," Journal of Raman Spectroscopy 31, 41-49 (2000).
43. I. Pastirk, V. V. Lozovoy, B. I. Grimberg,
E. J. Brown, and M. Dantus, "Control and characterization of intramolecular
dynamics with chirped femtosecond three-pulse four-wave mixing," Journal of
Physical Chemistry A 103, 10226-10236 (1999).
42. E. J. Brown, I.
Pastirk, B. I. Grimberg, V. V. Lozovoy, and M. Dantus, "Population and
coherence control by three-pulse four-wave mixing," Journal of Chemical
Physics 111, 3779-3782 (1999).
41. I. Pastirk, E. J.
Brown, B. I. Grimberg, V. V. Lozovoy, and M. Dantus, "Sequences for
controlling laser excitation with femtosecond three-pulse four-wave mixing,"
Faraday Discussions 401-424 (1999). General Discussions 77-106 and 455-491
(1999).
40. P. Backhaus, B.
Schmidt, and M. Dantus, "Control of photoassociation yield: a
quantum-dynamical study of the mercury system to explore the role of pulse
duration from nanoseconds to femtoseconds," Chemical Physics Letters 306,
18-24 (1999).
38. U. Marvet, Q. G.
Zhang, E. J. Brown, and M. Dantus, "Femtosecond dynamics of photoinduced
molecular detachment from halogenated alkanes. I. Transition state dynamics
and product channel coherence," Journal of Chemical Physics 109,
4415-4427 (1998).
37. E. J. Brown, I.
Pastirk, and M. Dantus, "Ultrafast rotational anisotropy measurements:
unidirectional detection," Journal of Physical Chemistry A 103,
2912-2916 (1999).
36. M. Dantus, “Femtosecond laser pulses: Principles and experiments." Edited by C. Rulliere, Springer-Verlag, New York (1998); and J. Am. Chem. Soc. 121, 8677 (1999).
35. K. S. Choi, R. Patschke, S. J. L. Billinge, M. J. Waner, M. Dantus, and M. G. Kanatzidis, "Charge density wave caused by reducing ThSe3 by one electron. Superstructure and short-range order in ATh(2)Se(6) (A = K, Rb) studied by X-ray diffraction, electron diffraction, and diffuse scattering," Journal of the American Chemical Society 120, 10706-10714 (1998).
34. Q. G. Zhang, U. Marvet, and M. Dantus, "Femtosecond dynamics of photoinduced molecular detachment from halogenated alkanes. II. Asynchronous concerted elimination of I-2 from CH2I2," Journal of Chemical Physics 109, 4428-4442 (1998).
33. U. Marvet, Q. Zhang, E. J. Brown and M. Dantus, “Femtosecond dynamics of photoinduced molecular detachment from halogenated alkanes I. Transition state dynamics and product channel coherence.” J. Chem. Phys. 109, 4415 (1998).
32. I. Pastirk, E. J. Brown, Q. G. Zhang, and M. Dantus, "Quantum control of the yield of a chemical reaction," Journal of Chemical Physics 108, 4375-4378 (1998).
31. U. Marvet, Q. Zhang
and M. Dantus, “Femtochemistry Dynamics of Unimolecular and Unrestricted
Bimolecular Reactions.” J. Phys. Chem. 102, 4111-4117 (1998). Special edition Femtochemistry III.
30.
M. J. Waner, M. Gilchrist, M. Schindler, and
M. Dantus, "Imaging the molecular dimensions and oligomerization of proteins
at liquid/solid interfaces," Journal of Physical Chemistry B 102,
1649-1657 (1998).
29. Q. Q. Zhang, U. Marvet, and M. Dantus,
"Concerted elimination dynamics from highly excited states," Faraday
Discussions 63-80 (1997).
28. P. Gross and M.
Dantus, "Femtosecond photoassociation: Coherence and implications for control
in bimolecular reactions," Journal of Chemical Physics 106, 8013-8021
(1997).
27. M. Dantus and P.
Gross, “Ultrafast Spectroscopy.” in Encyclopedia of Applied Physics 22,
431 (1998).
26. M. J. Waner, M.
Schindler and M. Dantus, “Investigation of Protein Structure at the
Solid/Liquid Interface with Atomic Force Microscopy (AFM).” Microsc. Microanal. 3, 1257 (1997).
25. U. Marvet and M. Dantus, "Femtosecond
observation of a concerted chemical reaction," Chemical Physics Letters 256,
57-62 (1996).
24. M. Dantus, U. Marvet, Q. Zhang, and E. J. Snyder, "Femtosecond dynamics of concerted elimination processes," Abstracts of Papers of the American Chemical Society 213, 372-PHYS (1997).
23.Marvet and M. Dantus, “Femtosecond photoassociation spectroscopy: Coherent bond formation.” in Femtochemistry: The Lausanne Conference , ed. M. Chergui, World Scientific, 138-139 (1996).
22. U. Marvet and M. Dantus, "Femtosecond
Photoassociation Spectroscopy - Coherent Bond Formation," Chemical Physics
Letters 245, 393-399 (1995).
21. M. Dantus, S. B. Kim, J. C. Williamson,
and A. H. Zewail, "Ultrafast Electron-Diffraction .5. Experimental Time
Resolution and Applications," Journal of Physical Chemistry 98,
2782-2796 (1994).
20.M. H. M. Janssen, M. Dantus, H. Guo, and A. H. Zewail, "Femtosecond Reaction Dynamics of Rydberg States - Methyl-Iodide," Chemical Physics Letters 214, 281-289 (1993).
19. J. C. Williamson, M. Dantus, S. B. Kim, and A. H. Zewail, "Ultrafast Diffraction and Molecular-Structure," Chemical Physics Letters 196, 529-534 (1992).
18. A. H. Zewail, M. Dantus, R. M. Bowman and A. Mokhtari, “Femtochemistry: recent advances and extension to high pressures.” J. Photochem. Photobiol. A: Chem. 62, pg. 301-319 (1992).
17. M. Dantus, M. H. M. Janssen, and A. H. Zewail, "Femtosecond Probing of Molecular-Dynamics by Mass-Spectrometry in a Molecular-Beam," Chemical Physics Letters 181, 281-287 (1991).
16. M. Dantus and G. Roberts, “Femtosecond Transition-State Spectroscopy and Chemical Reaction Dynamics.” Comments At. Mol. Phys. 26, 131 (1991).
15. R. M. Bowman, M. Dantus, and A. H. Zewail, “Femtosecond Multiphoton Probing of Higher-Energy Potentials.” Chem. Phys. Lett. 174, 546 (1990).
14. J. J. Gerdy, M. Dantus, R. M. Bowman, and A. H. Zewail, "Femtosecond Selective Control of Wave Packet Population," Chemical Physics Letters 171, 1-4 (1990).
13. .M. Dantus, R. M. Bowman, and A. H. Zewail,
"Femtosecond Laser Observations of Molecular Vibration and Rotation," Nature 343, 737-739 (1990).
12. M. Gruebele, G. Roberts, M. Dantus, R. M. Bowman, and A. H. Zewail, “Femtosecond temporal spectroscopy and direct inversion to the potential: Application to iodine.” Chem. Phys. Lett. 166, 459 (1990).
11. R. M. Bowman, M. Dantus, and A. H. Zewail, "Femtosecond Transition-State Spectroscopy of Iodine - from Strongly Bound to Repulsive Surface Dynamics," Chemical Physics Letters 161, 297-302 (1989).
10. M. Dantus, R. M.
Bowman, M. Gruebele, and A. H. Zewail, "Femtosecond Real-Time Probing of
Reactions .5. The Reaction of Ihgi," Journal of Chemical Physics 91,
7437-7450 (1989).
9. M. Dantus, R. M. Bowman, J. S. Baskin, and A. H. Zewail, "Femtosecond Real-Time Alignment in Chemical-Reactions," Chemical Physics Letters 159, 406-412 (1989).
8. R. M. Bowman, M. Dantus, and A. H. Zewail, "Femtochemistry of the Reaction - Ihgi-Star- Ihg=I -Star- Hgi+I," Chemical Physics Letters 156, 131-137 (1989)
7. M. Dantus, M. J. Rosker, and A. H. Zewail,
"Femtosecond Real-Time Probing of Reactions .2. The Dissociation Reaction of
ICN," Journal of Chemical Physics 89, 6128-6140 (1988).
6. M. J. Rosker, M. Dantus, and A. H. Zewail,
"Femtosecond Real-Time Probing of Reactions .1. The Technique," Journal of
Chemical Physics 89, 6113-6127 (1988).
5. M. J. Rosker,
M. Dantus, and A. H. Zewail, "Femtosecond Clocking of the Chemical-Bond,"
Science 241, 1200-1202 (1988).
4. M. Dantus, M. J.
Rosker, and A. H. Zewail, "Real-Time Femtosecond Probing of Transition-States
in Chemical-Reactions," Journal of Chemical Physics 87, 2395-2397
(1987).
3. L. W. Peng, M. Dantus,
A. H. Zewail, K. Kemnitz, J. M. Hicks, and K. B. Eisenthal, "Stepwise
Solvation of the Intramolecular-Charge-Transfer Molecule P-(Dimethylamino)Benzonitrile,"
Journal of Physical Chemistry 91, 6162-6167 (1987).
2. J. S. Baskin, M. Dantus, and A. H. Zewail, "Real-Time Measurements of IVR Versus Inferences from Spectral Broadening Data - the Alkylanilines Ring+Tail System," Chemical Physics Letters 130, 473-481 (1986).
1. I. Y. Chan and M.
Dantus, "Spectroscopic Study of Jet-Cooled Fluoranthene," Journal of Chemical
Physics 82, 4771-4776 (1985).