Using density functional theory, geometries and vibrational frequencies of linear chains NC2nN and HC2n+1N (n = 1 - 10) have been investigated. Time-dependent density functional theory (TD-DFF) has been used to c...Using density functional theory, geometries and vibrational frequencies of linear chains NC2nN and HC2n+1N (n = 1 - 10) have been investigated. Time-dependent density functional theory (TD-DFF) has been used to calculate the vertical transition energies and oscillator strengths for the x^1∑g^+→I^1∑u^+ transition in NC2,N (n = 1 -10) and X^1∑ → I^1∑^+ transition in HC2n+1N (n =1 -7). On the basis of present calculations, the explicit expressions for the size dependence of the excitation energy and the first adiabatic ionization energy in both carbon chains have been suggested.展开更多
基金This work was supported by the State Key Laboratory of Physical Chemistry of Solid Surfaces (Xiamen University), NSF of Henan Province and NNSF of China (20173042, 20233020, 20473062, 20021002)
文摘Using density functional theory, geometries and vibrational frequencies of linear chains NC2nN and HC2n+1N (n = 1 - 10) have been investigated. Time-dependent density functional theory (TD-DFF) has been used to calculate the vertical transition energies and oscillator strengths for the x^1∑g^+→I^1∑u^+ transition in NC2,N (n = 1 -10) and X^1∑ → I^1∑^+ transition in HC2n+1N (n =1 -7). On the basis of present calculations, the explicit expressions for the size dependence of the excitation energy and the first adiabatic ionization energy in both carbon chains have been suggested.
