Coincidence Momentum Imaging(CMI) is a powerful imaging technique that can determine the full momentum vectors of all particles released from a single parent molecule in coincidence and thus provide detailed informati...Coincidence Momentum Imaging(CMI) is a powerful imaging technique that can determine the full momentum vectors of all particles released from a single parent molecule in coincidence and thus provide detailed information on transient molecular structures.So far,the CMI technique has been extensively employed for investigating a variety of molecular reaction dynamics induced,e.g.,by particle collisions,intense laser fields and synchrotron radiation.In this article,we first introduce the principle of the CMI technique,which is followed by several typical experimental designs of the CMI systems realizing the coincidence momentum detections.We then present representative examples of studying molecular reaction dynamics using the CMI technique.展开更多
The analytical potential energy function of HDO is constructed at first using the many-body expansion method. The reaction dynamics of O+HD (v = 0, j = 0) in five product channels are all studied by quasi-classical...The analytical potential energy function of HDO is constructed at first using the many-body expansion method. The reaction dynamics of O+HD (v = 0, j = 0) in five product channels are all studied by quasi-classical trajectory (QCT) method. The results show that the long-lived complex compound HDO is the dominant product at low collision energy. With increasing collision energy, O+HD → OH+D and O+HD → OD+H exchange reactions will occur with remarkable characteristics, such as near threshold energies, different reaction probabilities, and different reaction cross sections, implying the isotopic effect between H and D. With further increasing collision energy (e.g., up to 502.08 kJ/mol), O+HD → O+H+D will occur and induce the complete dissociation into single O, H, and D atoms.展开更多
基金Sponsored by the National Natural Science Foundation of China(Grant Nos.61625501 and 61427816)Open Fund of the State Key Laboratory of High Field Laser Physics(SIOM)Fundamental Research Funds for the Central Universities
文摘Coincidence Momentum Imaging(CMI) is a powerful imaging technique that can determine the full momentum vectors of all particles released from a single parent molecule in coincidence and thus provide detailed information on transient molecular structures.So far,the CMI technique has been extensively employed for investigating a variety of molecular reaction dynamics induced,e.g.,by particle collisions,intense laser fields and synchrotron radiation.In this article,we first introduce the principle of the CMI technique,which is followed by several typical experimental designs of the CMI systems realizing the coincidence momentum detections.We then present representative examples of studying molecular reaction dynamics using the CMI technique.
基金Project supported by the National Natural Science Foundation of China (Grant No 10676022)
文摘The analytical potential energy function of HDO is constructed at first using the many-body expansion method. The reaction dynamics of O+HD (v = 0, j = 0) in five product channels are all studied by quasi-classical trajectory (QCT) method. The results show that the long-lived complex compound HDO is the dominant product at low collision energy. With increasing collision energy, O+HD → OH+D and O+HD → OD+H exchange reactions will occur with remarkable characteristics, such as near threshold energies, different reaction probabilities, and different reaction cross sections, implying the isotopic effect between H and D. With further increasing collision energy (e.g., up to 502.08 kJ/mol), O+HD → O+H+D will occur and induce the complete dissociation into single O, H, and D atoms.
