Subhendu Ghosh scite author profile

The direct dynamics trajectory surface hopping (DDTSH) method has been employed to study the reaction of C(P) with ethylene (CH). Our trajectory simulations show that at a reagent collision energy of 7.36 kcal/mol, there are two possible product channels: propargyl (HCCCH) + H and carbene (CH) + acetylene (HCCH). Estimated branching ratios based on trajectory propagations indicate that propargyl radical formation is the dominant channel contributing (94.1 ± 5.2) % of the overall products formation with (5.9 ± 1.7)% contribution from the minor CH + HCCH channel. These findings are consistent with earlier experimental observations and theoretical predictions that propargyl (HCCCH) formation is the dominant channel for the C(P) + CH collision reaction. Our trajectory simulations, however, unravel five distinctly different dynamical pathways, unlike earlier experimental and theoretical predictions of only two pathways proposed for the formation of propargyl radical, and three different dynamics are followed for the CH + HCCH channel (this channel was not detected experimentally). The computed translational energy distribution for the propargyl + H channel is narrower and showed peak maximum at a lower energy compared to the experimental one. While the center of mass product angular distribution based on our trajectory propagation is nearly isotropic in nature indicating formation of long-lived intermediate complexes, the experimental one was reported to be backward-forward distributed with more intensity in the forward direction indicating the formation of an osculating complex. Our trajectory surface hopping calculations confirm that the effect of intersystem crossing (ISC) is not important for the title reaction presumably because of weak spin-orbit coupling values (<10 cm) for the (C + CH) system. No trace of cyclic products formation was obtained from our trajectory simulations, which however was predicted to be a minor (2%) product channel, experimentally.

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Mn(I)-Catalyzed Preferential Electrophilic C3-Maleimidation in Quinoxaline Leading to Spirocyclization and Dehydrogenation of Succinimides

Ghosh

Khandelia

Panigrahi

et al. 2023

Org. Lett.

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A Mn(I)-catalyzed site-selective nondirected C3maleimidation of quinoxaline is established. Herein, the electrophilic C3-metalation precedes over the o-directed strategy to access diversely substituted quinoxaline-appended succinimides. The products undergo PIFA-promoted C(sp 2 )−C(sp 3 ) spirocyclization via π-electrons drifting from aryls and Selectfluor-mediated dehydrogenation of succinimide at room temperature.

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Photodissociation dynamics of propyne at 193 nm: a trajectory surface hopping study

Ghosh

Rauta

Maiti

2016

Phys. Chem. Chem. Phys.

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Photodissociation dynamics of propyne at 193 nm are studied using the fewest switches nonadiabatic trajectory surface hopping method on its first excited singlet electronic state (1(1)A''). The trajectories are propagated based on potential energies, gradients and nonadiabatic couplings calculated at the MRCIS(6,7) level with the 6-31++G(d,p) basis set. Our trajectory calculations have revealed that H + H3CCC is the major dissociation channel, which has also been predicted experimentally. For the primary photodissociation channel H + H3CCC we demonstrate that nonadiabatic dynamics do not play a significant role. This observation is however contradictory to most of the previously reported experimental predictions. The calculated product translation energy distribution for the acetylenic H atom elimination peaked at ∼ 18 kcal mol(-1), indicating that the dissociation occurs adiabatically on a moderately repulsive excited surface that correlates with the ground state products (CH3C ≡ C + H). The H atom elimination process from the methyl fragment involving a transition state, which has to compete with the acetylenic H atom dissociation channel with no barrier in the excited singlet surface, was found to be too less probable to make a contribution to product branching. We observed that a fewer but significant number of trajectories led to CH3 + CCH product formation which has not been observed experimentally when propyne is excited at 193 nm.

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Subhendu Ghosh

Dynamics of the O( 3 P, 1 D) + SiH 4 reaction: A trajectory surface hopping study

Dynamics of the C(³P) + Ethylene Reaction: A Trajectory Surface Hopping Study

Mn(I)-Catalyzed Preferential Electrophilic C3-Maleimidation in Quinoxaline Leading to Spirocyclization and Dehydrogenation of Succinimides

Photodissociation dynamics of propyne at 193 nm: a trajectory surface hopping study

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Subhendu Ghosh

Dynamics of the O( 3 P, 1 D) + SiH 4 reaction: A trajectory surface hopping study

Dynamics of the C(3P) + Ethylene Reaction: A Trajectory Surface Hopping Study

Mn(I)-Catalyzed Preferential Electrophilic C3-Maleimidation in Quinoxaline Leading to Spirocyclization and Dehydrogenation of Succinimides

Photodissociation dynamics of propyne at 193 nm: a trajectory surface hopping study

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Dynamics of the C(³P) + Ethylene Reaction: A Trajectory Surface Hopping Study