David R.H. Jones scite author profile

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A High Mass Resolution Study of the Interaction of Aromatic and Nitro-Aromatic Molecules with Intense Laser Fields

Tasker

Robson

Ledingham

et al. 2002

J. Phys. Chem. A

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The technique of femtosecond laser mass spectrometry has been applied to benzene, nitrobenzene, toluene and nitrotoluene using pulses of 80 fs and λ ) 800 nm (10 14 -10 16 W cm -2 ). The ultrafast laser pulses used were able to largely defeat the dissociation pathways associated with nanosecond ionization and produce a molecular ion for both the aromatics and the two photounstable nitro-aromatics. The high mass resolution (m/∆m ) 800) permitted, for the first time, the observation of various doubly charged species and allowed a study of the effect of the substituent NO 2 group on the multiple ionization process. It was found that the femtosecond laser irradiation of benzene and toluene enabled the production of a doubly charged cation envelope in each case along with an additional doubly ionized contribution from certain lower mass fragments. Doubly ionized species were also observed for the nitro-aromatics including, most notably the loss of NO 2 doubly charged ion ([M-NO 2 ] 2+ ) although a doubly charged parent was not observed. In addition, an NO 2 + ion was detected for both nitro-aromatics which was thought to be evidence of a "charge-separation" process involving a transient doubly charged molecular ion.

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David R.H. Jones

The free energies of solid-liquid interfaces

Engineering Materials and Their Properties

Radiation sources based on laser–plasma interactions

A High Mass Resolution Study of the Interaction of Aromatic and Nitro-Aromatic Molecules with Intense Laser Fields

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