Joseph McManus

Fragmentation dynamics of CS2 dications and trications following S 2p ionization

Journal of Chemical Physics American Institute of Physics 164:2 (2026) 24304

Authors:

Felix Allum, Chow-shing Lam, Benjamin Erk, Hubertus Bromberger, Philip H Bucksbaum, Mathew Britton, Michael Burt, Nagitha Ekanayake, Ian Gabalski, Diksha Garg, Eva Gougoula, David Heathcote, Andrew J Howard, Paul Hockett, David MP Holland, Sonu Kumar, Jason WL Lee, Joseph McManus, Jochen Mikosch, Dennis Milesevic, Russell S Minns, Christina C Papadopoulou, Christopher Passow, Weronika O Razmus, Anja Röder, Daniel Rolles, Arnaud Rouzée, Michael S Schuurman, Alcides Simao, Albert Stolow, Atia-Tul Noor, James Unwin, Claire Vallance, Tiffany Walmsley, Mark Brouard, Ruaridh Forbes

Abstract:

We present the results from a detailed study of the fragmentation dynamics of $\mathrm{CS}_{2}^{2+}$ and $\mathrm{CS}_{2}^{3+}$⁠, formed in intense femtosecond soft x-ray pulses above the sulfur 2p edge, primarily through single core photoionization from the S 2p site, and subsequent Auger–Meitner decay(s). By combining three-dimensional velocity map imaging with covariance analysis, we determine the relative momenta of the ions produced in each two- and three-body fragmentation channel, at significantly higher ion count rates than conventional coincidence measurements. We shed new light on the wide range of fragmentation channels observed from the CS2 dication and trication, including channels that involve ionization-induced bond formation and fragmentations producing undetected neutral cofragments. In the latter case, a “native frames” approach is used to isolate contributions from concerted and sequential fragmentations and extract dynamical information about each step of a concerted fragmentation process. While dications often fragment sequentially, the trication is dominated by concerted fragmentation. The main trication fragmentation channel into S⁺ + C⁺ + S⁺ can be well-approximated by classical Coulombic simulations of the ground-state geometry distribution, reflecting both the nature of the trication potential energy surface and the rapid multiple ionization prior to substantial structural dynamics. This study demonstrates ways in which fundamental insights into the fragmentation dynamics of polycations following x-ray ionization may be extracted, which will be beneficial to future studies that employ time-resolved x-ray Coulomb explosion imaging to study ultrafast photochemistry.

Time-resolved momentum imaging of UV photodynamics in structural isomers of iodopropane probed by site-selective XUV ionization

Physical Chemistry Chemical Physics Royal Society of Chemistry (2025)

Authors:

Felix Allum, Yoshiaki Kumagai, Kiyonobu Nagaya, James R Harries, Hiroshi Iwayama, Mathew Britton, Philip H Bucksbaum, Michael Burt, Mark Brouard, Briony Downes-Ward, Taran Driver, David Heathcote, Paul Hockett, Andrew J Howard, Jason WL Lee, Yusong Liu, Edwin Kukk, Joseph McManus, Dennis Milesevic, Russell S Minns, Akinobu Niozu, Johannes Niskanen, Andrew J Orr-Ewing, Shigeki Owada, Patrick Robertson, Daniel Rolles, Artem Rudenko, Kiyoshi Ueda, James Unwin, Claire Vallance, Tiffany Walmsley, Michael NR Ashfold, Ruaridh Forbes

Abstract:

The photodynamics of 1- and 2-iodopropane (1 and 2-IP) were studied in a time-resolved scheme incorporating ultraviolet (UV) excitation and extreme ultraviolet (XUV) probing, which initiates photoionization selectively from the I 4d core orbital. UV absorption in the A-band of both isomers leads to prompt C-I bond fission, with significant disposal of internal energy into the propyl radical product. Site-selective ionization enables a range of charge transfer (CT) processes between the nascent highly charged iodine ions and neutral propyl radicals, dependent on the interfragment distance at the instant of ionization. Subtle differences in the dynamics of these CT processes between the two isomers are observed. In 1-IP, the kinetic energies of iodine ions produced by UV photodissociation and subsequent XUV multiple ionization increased notably over the first few hundred femtoseconds, which could be understood in terms of differing gradients along the photodissociation coordinates of the neutral and polycationic states involved in the pump and probe steps, respectively. Led by a recent report of HI elimination in UV photoexcited 2-IP [Todt et al., Phys. Chem. Chem. Phys., 22(46), 27338 (2020)], we also model the most likely signatures of this process in the present experiment, and can identify signal in the 2-IP data (that is absent or significantly weaker in the data from the unbranched 1-IP isomer) that is consistent with such a process occurring on ultrafast timescales.

The femtochemistry of nitrobenzene following excitation at 240 nm

Communications Chemistry Nature Research 8:1 (2025) 268

Authors:

Chow-Shing Lam, Tai-Che Chou, Joseph McManus, Ciara Hodgkinson, Michael Burt, Mark Brouard

Abstract:

Although the photochemistry of nitrobenzene has been extensively studied, the assignment of fragmentation channels and their specific dynamics remains challenging. Here the photochemistry of nitrobenzene following 240 nm excitation into its S4 excited singlet state is investigated by femtosecond laser-induced ionization using an intense 800 nm pulse, coupled with time-resolved Coulomb explosion imaging and covariance mapping. We assign photochemical channels by observing correlations between the molecular fragment ions of the associated product pairs, enabling the time-resolved dynamics of channels leading to NO, NO2, and C6H5NO to be fully characterized. NO is produced via two distinct pathways, leading to translationally cold and hot photofragments with risetimes of ~ 8 ps and ~ 14 ps, respectively. NO2 photofragments are characterised by a bimodal risetime of ~ 8 ps and ≳ 2 ns, and can be detected within the first picosecond following ultra-violet photon absorption. C6H5NO is formed with a risetime of 17 ps. Kinetic energy disposals determined for the three chemical channels agree well with previous work. The techniques employed offer new opportunities to study the time-resolved photochemistry of relatively complex molecules in the gas phase.

Time-resolved probing of the iodobenzene C-band using XUV-induced electron transfer dynamics

ACS Physical Chemistry Au American Chemical Society 4:6 (2024) 620-631

Authors:

James Unwin, Weronika O Razmus, Felix Allum, James R Harries, Yoshiaki Kumagai, Kiyonobu Nagaya, Mathew Britton, Mark Brouard, Philip Bucksbaum, Mizuho Fushitani, Ian Gabalski, Tatsuo Gejo, Paul Hockett, Andrew J Howard, Hiroshi Iwayama, Edwin Kukk, Chow-shing Lam, Joseph McManus, Russell S Minns, Akinobu Niozu, Sekito Nishimuro, Johannes Niskanen, Shigeki Owada, James D Pickering, Daniel Rolles, James Somper, Kiyoshi Ueda, Shin-ichi Wada, Tiffany Walmsley, Joanne L Woodhouse, Ruaridh Forbes, Michael Burt, Emily M Warne

Abstract:

Time-resolved extreme ultraviolet spectroscopy was used to investigate photodissociation within the iodobenzene C-band. The carbon–iodine bond of iodobenzene was photolyzed at 200 nm, and the ensuing dynamics were probed at 10.3 nm (120 eV) over a 4 ps range. Two product channels were observed and subsequently isolated by using a global fitting method. Their onset times and energetics were assigned to distinct electron transfer dynamics initiated following site-selective ionization of the iodine photoproducts, enabling the electronic states of the phenyl fragments to be identified using a classical over-the-barrier model for electron transfer. In combination with previous theoretical work, this allowed the corresponding neutral photochemistry to be assigned to (1) dissociation via the 7B2, 8A2, and 8B1 states to give ground-state phenyl, Ph(X), and spin–orbit excited iodine and (2) dissociation through the 7A1 and 8B2 states to give excited-state phenyl, Ph(A), and ground-state iodine. The branching ratio was determined to be 87 ± 4% Ph(X) and 13 ± 4% Ph(A). Similarly, the corresponding amount of energy deposited into the internal phenyl modes in these channels was determined to be 44 ± 10 and 65 ± 21%, respectively, and upper bounds to the channel rise times were found to be 114 ± 6 and 310 ± 60 fs.

The role of momentum partitioning in covariance ion imaging analysis

Journal of Physical Chemistry A American Chemical Society 128:22 (2024) 4548-4560

Authors:

Tiffany Walmsley, Joseph McManus, Yoshiaki Kumagai, Kiyonobu Nagaya, James Harries, Hiroshi Iwayama, Michael NR Ashfold, Mathew Britton, Philip H Bucksbaum, Briony Downes-Ward, Taran Driver, David Heathcote, Paul Hockett, Andrew J Howard, Jason WL Lee, Yusong Liu, Edwin Kukk, Russell S Minns, Akinobu Niozu, Johannes Niskanen, Andrew J Orr-Ewing, Shigeki Owada, Patrick A Robertson, Daniel Rolles, Artem Rudenko, Kiyoshi Ueda, James Unwin, Claire Vallance, Dennis Milesevic, Patrick Robinson, James Unwin, Claire Vallance, Mark Brouard, Michael Burt, Felix Allum, Ruaridh Forbes

Abstract:

We present results from a covariance ion imaging study, which employs extensive filtering, on the relationship between fragment momenta to gain deeper insight into photofragmentation dynamics. A new data analysis approach is introduced that considers the momentum partitioning between the fragments of the breakup of a molecular polycation to disentangle concurrent fragmentation channels, which yield the same ion species. We exploit this approach to examine the momentum exchange relationship between the products, which provides direct insight into the dynamics of molecular fragmentation. We apply these techniques to extensively characterize the dissociation of 1-iodopropane and 2-iodopropane dications prepared by site-selective ionization of the iodine atom using extreme ultraviolet intense femtosecond laser pulses with a photon energy of 95 eV. Our assignments are supported by classical simulations, using parameters largely obtained directly from the experimental data.