posted on 2015-04-14, 00:00authored byLikai Du, Zhenggang Lan
Nonadiabatic
dynamics simulations have rapidly become an indispensable
tool for understanding ultrafast photochemical processes in complex
systems. Here, we present our recently developed on-the-fly nonadiabatic
dynamics package, JADE, which allows researchers to perform nonadiabatic
excited-state dynamics simulations of polyatomic systems at an all-atomic
level. The nonadiabatic dynamics is based on Tully’s surface-hopping
approach. Currently, several electronic structure methods (CIS, TDHF,
TDDFT(RPA/TDA), and ADC(2)) are supported, especially TDDFT, aiming
at performing nonadiabatic dynamics on medium- to large-sized molecules.
The JADE package has been interfaced with several quantum chemistry
codes, including Turbomole, Gaussian, and Gamess (US). To consider
environmental effects, the Langevin dynamics was introduced as an
easy-to-use scheme into the standard surface-hopping dynamics. The
JADE package is mainly written in Fortran for greater numerical performance
and Python for flexible interface construction, with the intent of
providing open-source, easy-to-use, well-modularized, and intuitive
software in the field of simulations of photochemical and photophysical
processes. To illustrate the possible applications of the JADE package,
we present a few applications of excited-state dynamics for various
polyatomic systems, such as the methaniminium cation, fullerene (C20), p-dimethylaminobenzonitrile (DMABN) and its primary amino
derivative aminobenzonitrile (ABN), and 10-hydroxybenzo[h]quinoline
(10-HBQ).