Fundamental studies of chemical reactions often draw molecular dynamics along a reaction coordinate in a calculated or suggested potential energy surface (PES) 1-5 . But fully mapping such dynamics experimentally, by following all nuclear motions in a timeresolved manner, that is the motions of wavepackets, is challenging and has not even been realized for the simple stereotypical bimolecular reaction 6-8 of A-B + C → A + B-C. Here we report such tracking of vibrational wavepacket trajectories during photo-induced bond formation in the gold trimer complex [Au(CN)2 -]3 in an aqueous solution, using femtosecond x-ray solution scattering (liquidography 9-12 ) at x-ray free electron lasers 13,14 . We find that the complex forms from an assembly of three monomers A, B and C clustered together through non-covalent interactions 15,16 and with the distance between A and B shorter than between B and C. Tracking of the wavepacket in three-dimensional nuclear coordinates (RAB, RBC, and RAC) reveals that within the first 60 fs after photoexcitation, a covalent bond forms between A and B to give A-B + C. The second covalent bond, between B and C, subsequently forms within 360 fs to give a linear and covalently-bonded trimer complex A-B-C. The trimer exhibits harmonic vibrations that we are also able to map, and unambiguously assign to specific normal modes using only the experimental data. More intense x-rays can in principle visualize the motion of not only highly-scattering atoms such as gold but also of lighter atoms such as carbon and nitrogen, which will open the door for the direct tracking of the atomic motions involved in many chemical reactions.The [Au(CN)2 -]3 complex has served as a valuable model system for studying photoinitiated processes in solution. Irradiation with ultraviolet light excites it from the ground state (S0) to the singlet state (S1), which within 20 fs undergoes intersystem crossing to reach a triplet excited state (T1') 18 . A further transition from T1' to another triplet excited state (T1) then occurs with a time constant of 1~2 ps, completing formation of covalent bonds and transformation of the complex from a bent to a linear structure 9,17,18 (see the Supplementary Information (SI) for details of the notations of electronic states).Formation of the bonds could involve any of the three possible candidate trajectories sketched in Fig. 1b. The equilibrium structure in the ground state determines the position of the
Photolysis of iodoform (CHI) in solution has been extensively studied, but its reaction mechanism remains elusive. In particular, iso-iodoform (iso-CHI-I) is formed as a product of the photolysis reaction, but its detailed structure is not known, and whether it is a major intermediate species has been controversial. Here, by using time-resolved X-ray liquidography, we determined the reaction mechanism of CHI photodissociation in cyclohexane as well as the structure of iso-CHI-I. Both iso-CHI-I and CHI radical were found to be formed within 100 ps with a branching ratio of 40:60. Iodine radicals (I), formed during the course of CHI photolysis, recombine nongeminately with either CHI or I. Based on our structural analysis, the I-I distance and the C-I-I angle of iso-CHI-I were determined to be 2.922 ± 0.004 Å and 133.9 ± 0.8°, respectively.
Ultrafast motion of molecules, particularly the coherent motion, has been intensively investigated as a key factor guiding the reaction pathways. Recently, X-ray free-electron lasers (XFELs) have been utilized to elucidate the ultrafast motion of molecules. However, the studies on proteins using XFELs have been typically limited to the crystalline phase, and proteins in solution have rarely been investigated. Here we applied femtosecond time-resolved X-ray solution scattering (fs-TRXSS) and a structure refinement method to visualize the ultrafast motion of a protein. We succeeded in revealing detailed ultrafast structural changes of homodimeric hemoglobin involving the coherent motion. In addition to the motion of the protein itself, the time-dependent change of electron density of the hydration shell was tracked. Besides, the analysis on the fs-TRXSS data of myoglobin allows for observing the effect of the oligomeric state on the ultrafast coherent motion.
Roaming reaction, defined as a reaction yielding products via reorientational motion in the long-range region (3 – 8 Å) of the potential, is a relatively recently proposed reaction pathway and is now regarded as a universal mechanism that can explain the unimolecular dissociation and isomerization of various molecules. The structural movements of the partially dissociated fragments originating from the frustrated bond fission at the onset of roaming, however, have been explored mostly via theoretical simulations and rarely observed experimentally. Here, we report an investigation of the structural dynamics during a roaming-mediated isomerization reaction of bismuth triiodide (BiI3) in acetonitrile solution using femtosecond time-resolved x-ray liquidography. Structural analysis of the data visualizes the atomic movements during the roaming-mediated isomerization process including the opening of the Bi-Ib-Ic angle and the closing of Ia-Bi-Ib-Ic dihedral angle, each by ~40°, as well as the shortening of the Ib···Ic distance, following the frustrated bond fission.
Optical Kerr effect (OKE) spectroscopy
is a method that measures
the time-dependent change of the birefringence induced by an optical
laser pulse using another optical laser pulse and has been used often
to study the ultrafast dynamics of molecular liquids. Here we demonstrate
an alternative method, femtosecond time-resolved X-ray liquidography
(fs-TRXL), where the microscopic structural motions related to the
OKE response can be monitored using a different type of probe, i.e.,
X-ray solution scattering. By applying fs-TRXL to acetonitrile and
a dye solution in acetonitrile, we demonstrate that different types
of molecular motions around photoaligned molecules can be resolved
selectively, even without any theoretical modeling, based on the anisotropy
of two-dimensional scattering patterns and extra structural information
contained in the q-space scattering data. Specifically,
the dynamics of reorientational (libration and orientational diffusion)
and translational (interaction-induced motion) motions are captured
separately by anisotropic and isotropic scattering signals, respectively.
Furthermore, the two different types of reorientational motions are
distinguished from each other by their own characteristic scattering
patterns and time scales. The measured time-resolved scattering signals
are in excellent agreement with the simulated scattering signals based
on a molecular dynamics simulation for plausible molecular configurations,
providing the detailed structural description of the OKE response
in liquid acetonitrile.
Salt bridge, one of the representative structural factors established by non-covalent interactions, plays a crucial role in stabilizing the structure and regulating the protein function, but its role in dynamic...
A typical metal complex has a central metal surrounded by multiple ligands, which greatly affect the properties of the whole complex. Although heteroleptic complexes often exhibit substantially different behaviors from...
X-ray free-electron lasers (XFELs) provide femtosecond X-ray pulses suitable for pump–probe time-resolved studies with a femtosecond time resolution. Since the advent of the first XFEL in 2009, recent years have...
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