Your search keyword '"Kočišek, Jaroslav"' showing total 33 results

1. Release of Neutrals in Electron-Induced Ligand Separation from MeCpPtMe 3 : Theory Meets Experiment.

Author

Lyshchuk H, Verkhovtsev AV, Kočišek J, Fedor J, and Solov'yov AV

Abstract

The interest in the electron impact-induced ligand release from MeCpPtMe 3 [trimethyl(methylcyclopentadienyl)platinum(IV)] is motivated by its widespread use as a precursor in focused electron and ion beam nanofabrication. By experimentally studying the electron impact dissociative ionization of MeCpPtMe 3 under single-collision conditions, we have found that the removal of two methyl radicals is energetically more favorable than the removal of one radical and even energetically comparable to the nondissociative ionization of MeCpPtMe 3 . This observation is explained by the structural rearrangement of the MeCpPtMe 3 + ion prior to dissociation, resulting in the removal of ethane instead of two methyl groups. This fragmentation pathway is computationally confirmed and studied by irradiation-driven molecular dynamics (IDMD) simulations. The formation of complex molecules in irradiation-induced molecular dissociation is a general phenomenon that can occur in various molecular systems. This study explains the puzzling results of previous experiments with MeCpPtMe 3 molecules and highlights the use of the IDMD approach to describe radiation-induced chemical transformations in molecular systems.

Published

2025

2. Dissociative Electron Attachment Dynamics of a Promising Cancer Drug Indicates Its Radiosensitizing Potential.

Author

Izadi F, Luxford TFM, Sedmidubská B, Arthur-Baidoo E, Kočišek J, Ončák M, and Denifl S

Subjects

Molecular Structure, Quantum Theory, Azetidines chemistry, Azetidines pharmacology, Electrons, Radiation-Sensitizing Agents chemistry, Radiation-Sensitizing Agents pharmacology, Antineoplastic Agents chemistry, Antineoplastic Agents pharmacology

Abstract

2-Bromo-1-(3,3-dinitroazetidin-1-yl)ethan-1-one (RRx-001) is a hypoxic cell chemotherapeutics with already demonstrated synergism in combined chemo-radiation therapy. The interaction of the compound with secondary low-energy electrons formed in large amounts during the physico-chemical phase of the irradiation may lead to these synergistic effects. The present study focuses on the first step of RRx-001 interaction with low-energy electrons in which a transient anion is formed and fragmented. Combination of two experiments allows us to disentangle the decay of the RRx-001 anion on different timescales. Sole presence of the electron initiates rapid dissociation of NO 2 and HNO 2 neutrals while NO 2 - and Br - anions are produced both directly and via intermediate complexes. Based on our quantum chemical calculations, we propose that bidirectional state switching between π*(NO 2 ) and σ*(C-Br) states explains the experimental spectra. The fast dynamics monitored will impact the condensed phase chemistry of the anion as well., (© 2024 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2024

3. Condensed Matter Systems Exposed to Radiation: Multiscale Theory, Simulations, and Experiment.

Author

Solov'yov AV, Verkhovtsev AV, Mason NJ, Amos RA, Bald I, Baldacchino G, Dromey B, Falk M, Fedor J, Gerhards L, Hausmann M, Hildenbrand G, Hrabovský M, Kadlec S, Kočišek J, Lépine F, Ming S, Nisbet A, Ricketts K, Sala L, Schlathölter T, Wheatley AEH, and Solov'yov IA

Abstract

This roadmap reviews the new, highly interdisciplinary research field studying the behavior of condensed matter systems exposed to radiation. The Review highlights several recent advances in the field and provides a roadmap for the development of the field over the next decade. Condensed matter systems exposed to radiation can be inorganic, organic, or biological, finite or infinite, composed of different molecular species or materials, exist in different phases, and operate under different thermodynamic conditions. Many of the key phenomena related to the behavior of irradiated systems are very similar and can be understood based on the same fundamental theoretical principles and computational approaches. The multiscale nature of such phenomena requires the quantitative description of the radiation-induced effects occurring at different spatial and temporal scales, ranging from the atomic to the macroscopic, and the interlinks between such descriptions. The multiscale nature of the effects and the similarity of their manifestation in systems of different origins necessarily bring together different disciplines, such as physics, chemistry, biology, materials science, nanoscience, and biomedical research, demonstrating the numerous interlinks and commonalities between them. This research field is highly relevant to many novel and emerging technologies and medical applications.

Published

2024

4. Electron-induced ligand loss from iron tetracarbonyl methyl acrylate.

Author

Lyshchuk H, Chaudhary A, Luxford TFM, Ranković M, Kočišek J, Fedor J, McElwee-White L, and Nag P

Abstract

We probe the separation of ligands from iron tetracarbonyl methyl acrylate (Fe(CO) 4 (C 4 H 6 O 2 ) or Fe(CO) 4 MA) induced by the interaction with free electrons. The motivation comes from the possible use of this molecule as a nanofabrication precursor and from the corresponding need to understand its elementary reactions fundamental to the electron-induced deposition. We utilize two complementary electron collision setups and support the interpretation of data by quantum chemical calculations. This way, both the dissociative ionization and dissociative electron attachment fragmentation channels are characterized. Considerable differences in the degree of precursor fragmentation in these two channels are observed. Interesting differences also appear when this precursor is compared to structurally similar iron pentacarbonyl. The present findings shed light on the recent electron-induced chemistry of Fe(CO) 4 MA on a surface under ultrahigh vacuum., (Copyright © 2024, Lyshchuk et al.)

Published

2024

5. Interaction of low-energy electrons with radiosensitizers.

Author

Sedmidubská B and Kočišek J

Abstract

We provide an experimentalist's perspective on the present state-of-the-art in the studies of low-energy electron interactions with common radiosensitizers, including compounds used in combined chemo-radiation therapy and their model systems. Low-energy electrons are important secondary species formed during the interaction of ionizing radiation with matter. Their role in the radiation chemistry of living organisms has become an important topic for more than 20 years. With the increasing number of works and reviews in the field, we would like to focus here on a very narrow area of compounds that have been shown to have radio-sensitizing properties on the one hand, and high reactivity towards low-energy electrons on the other hand. Gas phase experiments studying electron attachment to isolated molecules and environmental effects on reaction dynamics are reviewed for modified DNA components, nitroimidazoles, and organometallics. In the end, we provide a perspective on the future directions that may be important for transferring the fundamental knowledge about the processes induced by low-energy electrons into practice in the field of rational design of agents for concomitant chemo-radiation therapy.

Published

2024

6. Electron Energy Loss Processes in Methyl Methacrylate: Excitation and Bond Breaking.

Author

Luxford TFM, Fedor J, and Kočišek J

Abstract

Details of electron-induced chemistry of methyl methacrylate (MMA) upon complexation are revealed by combining gas-phase 2D electron energy loss spectroscopy with electron attachment spectroscopy of isolated MMA and its clusters. We show that even though isolated MMA does not form stable parent anions, it efficiently thermalizes the incident electrons via intramolecular vibrational redistribution, leading to autodetachment of slow electrons. This autodetachment channel is reduced in clusters due to intermolecular energy transfer and stabilization of parent molecular anions. Bond breaking via dissociative electron attachment leads to an extensive range of anion products. The dominant OCH 3 - channel is accessible via core-excited resonances with threshold above 5 eV, despite the estimated thermodynamic threshold below 3 eV. This changes in clusters, where M n OCH 3 - anions are observed in a lower-lying resonance due to neutral dissociation of the 1 (n, π*) state and electron self-scavenging. The present findings have implications for electron-induced chemistry in lithography with poly(methyl methacrylate).

Published

2023

7. Non-ergodic fragmentation upon collision-induced activation of cysteine-water cluster cations.

Author

Tiefenthaler L, Scheier P, Erdmann E, Aguirre NF, Díaz-Tendero S, Luxford TFM, and Kočišek J

Abstract

Cysteine-water cluster cations Cys(H 2 O) 3,6 + and Cys(H 2 O) 3,6 H + are assembled in He droplets and probed by tandem mass spectrometry with collision-induced activation. Benchmark experimental data for this biologically important system are complemented with theory to elucidate the details of the collision-induced activation process. Experimental energy thresholds for successive release of water are compared to water dissociation energies from DFT calculations showing that clusters do not only fragment exclusively by sequential emission of single water molecules but also by the release of small water clusters. Release of clustered water is observed also in the ADMP (atom centered density matrix propagation) molecular dynamics model of small Cys(H 2 O) 3 + and Cys(H 2 O) 3 H + clusters. For large clusters Cys(H 2 O) 6 + and Cys(H 2 O) 6 H + the less computationally demanding statistical Microcanonical Metropolis Monte-Carlo method (M 3 C) is used to model the experimental fragmentation patterns. We are able to detail the energy redistribution in clusters upon collision activation. In the present case, about two thirds of the collision energy redistribute via an ergodic process, while the remaining one third is transferred into a non-ergodic channel leading to ejection of a single water molecule from the cluster. In contrast to molecular fragmentation, which can be well described by statistical models, modelling of collision-induced activation of weakly bound clusters requires inclusion of non-ergodic processes.

Published

2023

8. Viewpoints on the 11th International Meeting on Atomic and Molecular Physics and Chemistry.

Author

Sala L, Luxford TFM, Ranković M, and Kočišek J

Subjects

Congresses as Topic, Humans, Physics, Chemistry

Published

2022

9. Low-Energy Electron Induced Reactions in Metronidazole at Different Solvation Conditions.

Author

Lochmann C, Luxford TFM, Makurat S, Pysanenko A, Kočišek J, Rak J, and Denifl S

Abstract

Metronidazole belongs to the class of nitroimidazole molecules and has been considered as a potential radiosensitizer for radiation therapy. During the irradiation of biological tissue, secondary electrons are released that may interact with molecules of the surrounding environment. Here, we present a study of electron attachment to metronidazole that aims to investigate possible reactions in the molecule upon anion formation. Another purpose is to elucidate the effect of microhydration on electron-induced reactions in metronidazole. We use two crossed electron/molecular beam devices with the mass-spectrometric analysis of formed anions. The experiments are supported by quantum chemical calculations on thermodynamic properties such as electron affinities and thresholds of anion formation. For the single molecule, as well as the microhydrated condition, we observe the parent radical anion as the most abundant product anion upon electron attachment. A variety of fragment anions are observed for the isolated molecule, with NO 2 - as the most abundant fragment species. NO 2 - and all other fragment anions except weakly abundant OH - are quenched upon microhydration. The relative abundances suggest the parent radical anion of metronidazole as a biologically relevant species after the physicochemical stage of radiation damage. We also conclude from the present results that metronidazole is highly susceptible to low-energy electrons.

Published

2022

10. Different Mechanisms of DNA Radiosensitization by 8-Bromoadenosine and 2'-Deoxy-2'-fluorocytidine Observed on DNA Origami Nanoframe Supports.

Author

Sala L, Lyshchuk H, Šáchová J, Chvátil D, and Kočišek J

Subjects

Adenosine analogs & derivatives, DNA Damage, Deoxycytidine analogs & derivatives, DNA radiation effects, DNA Repair

Abstract

DNA origami nanoframes with two parallel DNA sequences are used to evaluate the effect of nucleoside substituents on radiation-induced DNA damage. Double strand breaks (DSB) of DNA are counted using atomic force microscopy (AFM), and total number of lesions is evaluated using real-time polymerase chain reaction (RT-PCR). Enhanced AT or GC content does not increase the number of DNA strand breaks. Incorporation of 8-bromoadenosine results in the highest enhancement in total number of lesions; however, the highest enhancement in DSB is observed for 2'-deoxy-2'-fluorocytidine, indicating different mechanisms of radiosensitization by nucleoside analogues with the halogen substituent on base or sugar moieties, respectively. "Bystander" effects are observed, when the number of DSB in a sequence is enhanced by a substituent in the parallel DNA sequence. The present approach eliminates limitations of previously developed methods and motivates detailed studies of poorly understood conformation or bystander effects in radiation induced damage to DNA.

Published

2022

11. Controlling the diversity of ion-induced fragmentation pathways by N -methylation of amino acids.

Author

Barreiro-Lage D, Nicolafrancesco C, Kočišek J, Luna A, Kopyra J, Alcamí M, Huber BA, Martín F, Domaracka A, Rousseau P, and Díaz-Tendero S

Subjects

Density Functional Theory, Glycine analogs & derivatives, Ions, Methylation, Molecular Dynamics Simulation, Glycine chemistry, Sarcosine chemistry

Abstract

We present a combined experimental and theoretical study of the fragmentation of singly and doubly N -methylated glycine (sarcosine and N , N -dimethyl glycine, respectively) induced by low-energy (keV) O 6+ ions. Multicoincidence mass spectrometry techniques and quantum chemistry simulations ( ab initio molecular dynamics and density functional theory) allow us to characterise different fragmentation pathways as well as the associated mechanisms. We focus on the fragmentation of doubly ionised species, for which coincidence measurements provide unambiguous information on the origin of the various charged fragments. We have found that single N -methylation leads to a larger variety of fragmentation channels than in no methylation of glycine, while double N -methylation effectively closes many of these fragmentation channels, including some of those appearing in pristine glycine. Importantly, the closure of fragmentation channels in the latter case does not imply a protective effect by the methyl group.

Published

2022

12. Electron attachment to isolated and microhydrated favipiravir.

Author

Sedmidubská B, Luxford TFM, and Kočišek J

Subjects

Electrons, Water chemistry, Amides chemistry, Amides isolation & purification, Pyrazines chemistry, Pyrazines isolation & purification

Abstract

Electron attachment and its equivalent in complex environments, single-electron reduction, are important in many biological processes. Here, we experimentally study the electron attachment to favipiravir, a well-known antiviral agent. Electron attachment spectroscopy is used to explore the energetics of associative (AEA) and dissociative (DEA) electron attachment to isolated favipiravir. AEA dominates the interaction and the yields of the fragment anions after DEA are an order of magnitude lower than that of the parent anion. DEA primary proceeds via decomposition of the CONH 2 functional group, which is supported by reaction threshold calculations using ab initio methods. Mass spectrometry of small favipiravir-water clusters demonstrates that a lot of energy is transferred to the solvent upon electron attachment. The energy gained upon electron attachment, and the high stability of the parent anion were previously suggested as important properties for the action of several electron-affinic radiosensitizers. If any of these mechanisms cause synergism in chemo-radiation therapy, favipiravir could be repurposed as a radiosensitizer.

Published

2021

13. Electron attachment to microhydrated 4-nitro- and 4-bromo-thiophenol.

Author

Sala L, Sedmidubská B, Vinklárek I, Fárník M, Schürmann R, Bald I, Med J, Slavíček P, and Kočišek J

Abstract

We investigate the effect of microhydration on electron attachment to thiophenols with halogen (Br) and nitro (NO 2 ) functional groups in the para position. We focus on the formation of anions upon the attachment of low-energy electrons with energies below 8 eV to heterogeneous clusters of the thiophenols with water. For nitro-thiophenol (NTP), the primary reaction channel observed is the associative electron attachment, irrespective of the microhydration. On the other hand, bromothiophenol (BTP) fragments significantly upon the electron attachment, producing Br - and (BTP-H) - anions. Microhydration suppresses fragmentation of both molecules, however in bromothiophenol, the Br - channel remains intense and Br(H 2 O) n - hydrated fragment clusters are observed. The results are supported by the reaction energetics obtained from ab initio calculations. Different dissociation dynamics of NTP and BTP can be related to different products of their plasmon induced reactions on Au nanoparticles. Computational modeling of the simplified BTP(H 2 O) system indicates that the electron attachment products reflect the structure of neutral precursor clusters - the anion dissociation dynamics is controlled by the hydration site.

Published

2021

14. Folding DNA into origami nanostructures enhances resistance to ionizing radiation.

Author

Sala L, Zerolová A, Rodriguez A, Reimitz D, Davídková M, Ebel K, Bald I, and Kočišek J

Subjects

DNA, Nanotechnology, Nucleic Acid Conformation, Radiation, Ionizing, Nanostructures

Abstract

We report experimental results on damage induced by ionizing radiation to DNA origami triangles which are commonly used prototypes for scaffolded DNA origami nanostructures. We demonstrate extreme stability of DNA origami upon irradiation, which is caused by (i) the multi-row design holding the shape of the origami even after severe damage to the scaffold DNA and (ii) the reduction of damage to the scaffold DNA due to the protective effect of the folded structure. With respect to damage induced by ionizing radiation, the protective effect of the structure is superior to that of a naturally paired DNA double helix. Present results allow estimating the stability of scaffolded DNA origami nanostructures in applications such as nanotechnology, pharmacy or in singulo molecular studies where they are exposed to ionizing radiation from natural and artificial sources. Additionally, possibilities are opened for scaffolded DNA use in the design of radiation-resistant and radio-sensitive materials.

Published

2021

15. Stability of pyruvic acid clusters upon slow electron attachment.

Author

Pysanenko A, Grygoryeva K, Kočišek J, Kumar T P R, Fedor J, Ončák M, and Fárník M

Abstract

Pyruvic acid represents a key molecule in prebiotic chemistry and it has recently been proposed to be synthesized on interstellar ices. In order to probe the stability of pyruvic acid in the interstellar medium with respect to decomposition by slow electrons, we investigate the electron attachment to its homomolecular and heteromolecular clusters. Using mass spectrometry, we follow the changes in the fragmentation pattern and its dependence on the electron energy for various cluster sizes of pure and microhydrated pyruvic acid. The assignment of fragmentation reaction pathways is supported by ab initio calculations. The fragmentation degree dramatically decreases upon clustering. This decrease is even stronger in the heteromolecular clusters of pyruvic acid with water, where the non-dissociative attachment is by far the strongest channel. In the homomolecular clusters, the dissociative channel leading to dehydrogenation is active over a larger electron energy range than in the isolated molecules. To probe the role of the self-scavenging effects, we explore the excited states of pyruvic acid. This has been done both experimentally, by using electron energy loss spectroscopy, and theoretically, by photochemical calculations. Data on both optically-allowed and forbidden states allow for the explanation of processes emerging upon clustering.

Published

2021

16. Pickup and reactions of molecules on clusters relevant for atmospheric and interstellar processes.

Author

Fárník M, Fedor J, Kočišek J, Lengyel J, Pluhařová E, Poterya V, and Pysanenko A

Abstract

In this perspective, we review experiments with molecules picked up on large clusters in molecular beams with the focus on the processes in atmospheric and interstellar chemistry. First, we concentrate on the pickup itself, and we discuss the pickup cross sections. We measure the uptake of different atmospheric molecules on mixed nitric acid-water clusters and determine the accommodation coefficients relevant for aerosol formation in the Earth's atmosphere. Then the coagulation of the adsorbed molecules on the clusters is investigated. In the second part of this perspective, we review examples of different processes triggered by UV-photons or electrons in the clusters with embedded molecules. We start with the photodissociation of hydrogen halides and Freon CF 2 Cl 2 on ice nanoparticles in connection with the polar stratospheric ozone depletion. Next, we mention reactions following the excitation and ionization of the molecules adsorbed on clusters. The first ionization-triggered reaction observed between two different molecules picked up on the cluster was the proton transfer between methanol and formic acid deposited on large argon clusters. Finally, negative ion reactions after slow electron attachment are illustrated by two examples: mixed nitric acid-water clusters, and hydrogen peroxide deposited on large Ar N and (H 2 O) N clusters. The selected examples are discussed from the perspective of the atmospheric and interstellar chemistry, and several future directions are proposed.

Published

2021

17. Carboxylation Enhances Fragmentation of Furan upon Resonant Electron Attachment.

Author

Zawadzki M, Luxford TFM, and Kočišek J

Abstract

We report a dissociative electron attachment study to 2-furoic acid (C 5 H 4 O 3 ) isolated in a gas phase, which is a model molecule consisting of a carboxylic group and a furan ring. Dissociation of furan by low energy electrons is accessible only via electronic excited Feshbach resonances at energies of incident electrons above 5 eV. On the other hand, carboxylic acids are well-known to dissociate via attachment of electrons at subexcitation energies. Here we elucidate how the electron and proton transfer reactions induced by carboxylation influence stability of the furan ring. Overlap of the furan and carboxyl π orbitals results in transformation of the nondissociative π 2 resonance of the furan ring to a dissociative resonance. The interpretation of hydrogen transfer reactions is supported by experimental studies of 3-methyl-2-furoic and 5-methyl-2-furoic acids (C 6 H 6 O 3 ) and density functional theory (DFT) calculations.

Published

2020

18. 5-Nitro-2,4-Dichloropyrimidine as an Universal Model for Low-Energy Electron Processes Relevant for Radiosensitization.

Author

Luxford TFM, Pshenichnyuk SA, Asfandiarov NL, Perečko T, Falk M, and Kočišek J

Subjects

Cell Line, Tumor, Humans, Hypopharyngeal Neoplasms chemistry, Hypopharyngeal Neoplasms drug therapy, Models, Chemical, Models, Molecular, Nitro Compounds chemistry, Nitro Compounds pharmacology, Pyrimidines chemistry, Radiation, Ionizing, Radiation-Sensitizing Agents chemistry, Squamous Cell Carcinoma of Head and Neck chemistry, Squamous Cell Carcinoma of Head and Neck drug therapy, Electrons, Hypopharyngeal Neoplasms radiotherapy, Pyrimidines pharmacology, Radiation-Sensitizing Agents pharmacology, Squamous Cell Carcinoma of Head and Neck radiotherapy

Abstract

We report experimental results of low-energy electron interactions with.

Published

2020

19. Dissociation of Valine Cluster Cations.

Author

Tiefenthaler L, Ončák M, Kollotzek S, Kočišek J, and Scheier P

Abstract

Independently of the preparation method, for cluster cations of aliphatic amino acids, the protonated form M n H + is always the dominant species. This is a surprising fact considering that in the gas phase, they dissociate primarily by the loss of 45 Da, i.e., the loss of the carboxylic group. In the present study, we explore the dissociation dynamics of small valine cluster cations M n + and their protonated counterparts M n H + via collision-induced dissociation experiments and ab initio calculations with the aim to elucidate the formation of M n H + -type cations from amino acid clusters. For the first time, we report the preparation of valine cluster cations M n + in laboratory conditions, using a technique of cluster ion assembly inside He droplets. We show that the M n + cations cooled down to He droplet temperature can dissociate to form both M n -1 H + and [M n -COOH] + ions. With increasing internal energy, the M n -1 H + formation channel becomes dominant. M n -1 H + ions then fragment nearly exclusively by monomer loss, describing the high abundance of protonated clusters in the mass spectra of amino acid clusters.

Published

2020

20. Interaction of 4-nitrothiophenol with low energy electrons: Implications for plasmon mediated reactions.

Author

Schürmann R, Luxford TFM, Vinklárek IS, Kočišek J, Zawadzki M, and Bald I

Abstract

The reduction of 4-nitrothiophenol (NTP) to 4-4'-dimercaptoazobenzene (DMAB) on laser illuminated noble metal nanoparticles is one of the most widely studied plasmon mediated reactions. The reaction is most likely triggered by a transfer of low energy electrons from the nanoparticle to the adsorbed molecules. Besides the formation of DMAB, dissociative side reactions of NTP have also been observed. Here, we present a crossed electron-molecular beam study of free electron attachment to isolated NTP in the gas-phase. Negative ion yields are recorded as a function of the electron energy, which helps to assess the accessibility of single electron reduction pathways after photon induced electron transfer from nanoparticles. The dominant process observed with isolated NTP is associative electron attachment leading to the formation of the parent anion of NTP. Dissociative electron attachment pathways could be revealed with much lower intensities, leading mainly to the loss of functional groups. The energy gained by one electron reduction of NTP may also enhance the desorption of NTP from nanoparticles. Our supporting experiments with small clusters, then, show that further reaction steps are necessary after electron attachment to produce DMAB on the surfaces.

Published

2020

21. Ion and radical chemistry in (H 2 O 2 ) N clusters.

Author

Pysanenko A, Pluhařová E, Vinklárek IS, Rakovský J, Poterya V, Kočišek J, and Fárník M

Abstract

We investigate the ionization induced chemistry of hydrogen peroxide in (H 2 O 2 ) N clusters generated after the pickup of individual H 2 O 2 molecules on large free Ar M , M[combining macron]≈ 160, nanoparticles in molecular beams. Positive and negative ion mass spectra are recorded after an electron ionization of the clusters at energies 5-70 eV and after a slow electron attachment (below 4 eV), respectively. The spectra demonstrate that (H 2 O 2 ) N clusters with N≥ 20 are formed on argon nanoparticles. This is the first experimental report on hydrogen peroxide clusters in molecular beams. The major negative cluster ion series (H 2 O 2 ) n O 2 - indicates O 2 - ion formation. The dissociative electron attachment to H 2 O 2 molecules in the gas phase yielded only OH - and O - (Nandi et al., Chem. Phys. Lett., 2003, 373, 454). These ions and the series containing them are much less abundant in the clusters. We propose a sequence of ion-molecule and radical reactions to explain the formation of O 2 - , HO 2 - and other ions observed in the negatively charged cluster ion series. Since hydrogen peroxide plays an important role in many areas of chemistry from the Earth's atmosphere to biological tissues, our study opens new horizons for experimental investigations of hydrogen peroxide chemistry in complex environments.

Published

2020

22. Solvation of Silver Ions in Noble Gases He, Ne, Ar, Kr, and Xe.

Author

Mahmoodi-Darian M, Martini P, Tiefenthaler L, Kočišek J, Scheier P, and Echt O

Abstract

We use a novel technique to solvate silver cations in small clusters of noble gases. The technique involves the formation of large, superfluid helium nanodroplets that are subsequently electron ionized, mass-selected by deflection in an electric field, and doped with silver atoms and noble gases (Ng) in pickup cells. Excess helium is then stripped from the doped nanodroplets by multiple collisions with helium gas at room temperature, producing cluster ions that contain no more than a few dozen noble gas atoms and just a few (or no) silver atoms. Under gentle stripping conditions, helium atoms remain attached to the cluster ions, demonstrating their low vibrational temperature. Under harsher stripping conditions, some of the heavier noble gas atoms will be evaporated as well, thus enriching stable clusters of Ng n Ag m + at the expense of less stable ones. This results in local anomalies in the cluster ion abundance, which is measured in a high-resolution time-of-flight mass spectrometer. On the basis of these data, we identify specific "magic" sizes n of particularly stable ions. There is no evidence, however, for enhanced stability of Ng 2 Ag + , in contrast to the high stability of Ng 2 Au + that derives from the covalent nature of the bond for heavy noble gases. "Magic" sizes are also identified for Ag 2 + dimer ions complexed with He or Kr. Structural models will be tentatively proposed. A sequence of magic numbers n = 12, 32, and 44, indicative of three concentric solvation shells of icosahedral symmetry, is observed for He n H 2 O + .

Published

2019

23. Ring Formation and Hydration Effects in Electron Attachment to Misonidazole.

Author

Ončák M, Meißner R, Arthur-Baidoo E, Denifl S, Luxford TFM, Pysanenko A, Fárník M, Pinkas J, and Kočišek J

Subjects

Models, Molecular, Models, Theoretical, Molecular Structure, Solvents, Spectrum Analysis, Water, Electrons, Misonidazole chemistry

Abstract

We study the reactivity of misonidazole with low-energy electrons in a water environment combining experiment and theoretical modelling. The environment is modelled by sequential hydration of misonidazole clusters in vacuum. The well-defined experimental conditions enable computational modeling of the observed reactions. While the NO 2 - dissociative electron attachment channel is suppressed, as also observed previously for other molecules, the OH - channel remains open. Such behavior is enabled by the high hydration energy of OH - and ring formation in the neutral radical co-fragment. These observations help to understand the mechanism of bio-reductive drug action. Electron-induced formation of covalent bonds is then important not only for biological processes but may find applications also in technology.

Published

2019

24. Proton transfer from pinene stabilizes water clusters.

Author

Poštulka J, Slavíček P, Domaracka A, Pysanenko A, Fárník M, and Kočišek J

Abstract

We ionize small mixed pinene-water clusters by electron impact or by using photons after sodium doping and analyze the products by mass spectrometry. Electron ionization results in the formation of pure pinene, mixed pinene-water and protonated water cluster cations. The "fragmentation free" photoionization after sodium doping results into the formation of only water-Na + clusters with a mean cluster size below that observed after electron ionization. We show that protonated water clusters are formed both directly and indirectly via pinene ionziation. The latter pathway is detailed by ab intio calculations, demonstrating the feasibility of proton transfer from pinene for larger water clusters. In small clusters, the proton transfer reaction is controlled by proton solvation energy and we can thus estimate its value for finite size clusters. The observed stabilization mechanism of water clusters may contribute to the formation of cloud condensation nuclei in the atmosphere.

Published

2019

25. Low-energy electrons transform the nimorazole molecule into a radiosensitiser.

Author

Meißner R, Kočišek J, Feketeová L, Fedor J, Fárník M, Limão-Vieira P, Illenberger E, and Denifl S

Subjects

Humans, Nimorazole therapeutic use, Oxidation-Reduction, Radiation-Sensitizing Agents therapeutic use, Chemoradiotherapy, Electrons, Neoplasms therapy, Nimorazole chemistry, Radiation-Sensitizing Agents chemistry

Abstract

While matter is irradiated with highly-energetic particles, it may become chemically modified. Thereby, the reactions of free low-energy electrons (LEEs) formed as secondary particles play an important role. It is unknown to what degree and by which mechanism LEEs contribute to the action of electron-affinic radiosensitisers applied in radiotherapy of hypoxic tumours. Here we show that LEEs effectively cause the reduction of the radiosensitiser nimorazole via associative electron attachment with the cross-section exceeding most of known molecules. This supports the hypothesis that nimorazole is selectively cytotoxic to tumour cells due to reduction of the molecule as prerequisite for accumulation in the cell. In contrast, dissociative electron attachment, commonly believed to be the source of chemical activity of LEEs, represents only a minor reaction channel which is further suppressed upon hydration. Our results show that LEEs may strongly contribute to the radiosensitising effect of nimorazole via associative electron attachment.

Published

2019

26. Electron Attachment to Microhydrated Deoxycytidine Monophosphate.

Author

Kočišek J, Sedmidubská B, Indrajith S, Fárník M, and Fedor J

Subjects

Electron Transport, Models, Molecular, Molecular Conformation, Deoxycytidine Monophosphate chemistry

Abstract

DNA constituents are effectively decomposed via dissociative electron attachment (DEA). However, the DEA contribution to radiation damage in living tissues is a subject of ongoing discussion. We address an essential question, how aqueous environment influences the DEA to DNA. In particular, we report experimental fragmentation patterns for DEA to microhydrated 2-deoxycytidine 5-monophosphate (dCMP). Isolated dCMP was previously set as a model to describe mechanisms of DNA-strand breaks induced by secondary electrons and decomposes primarily by dissociation of the C-O phosphoester bond. We show that hydrated molecules decompose via dissociation of the C-N glycosidic bond followed by dissociation of the P-O bond. This significant change of the proposed mechanism can be interpreted by a reactive role of water in the postattachment dynamics. Comparison of the fragmentation with previous macroscopic irradiation studies suggests that the actual contribution of DEA to DNA radiation damage in living tissue is rather small.

Published

2018

27. Suppression of low-energy dissociative electron attachment in Fe(CO) 5 upon clustering.

Author

Lengyel J, Papp P, Matejčík Š, Kočišek J, Fárník M, and Fedor J

Abstract

In this work, we probe anion production upon electron interaction with Fe(CO) 5 clusters using two complementary cluster-beam setups. We have identified two mechanisms that lead to synthesis of complex anions with mixed Fe/CO composition. These two mechanisms are operative in distinct electron energy ranges. It is shown that the elementary decomposition mechanism that has received perhaps the most attention in recent years (i.e., dissociative electron attachment at energies close to 0 eV) becomes suppressed upon increasing aggregation of iron pentacarbonyl. We attribute this suppression to the electrostatic shielding of a long-range interaction that strongly enhances the dissociative electron attachment in isolated Fe(CO) 5 .

Published

2017

28. Electron-triggered chemistry in HNO 3 /H 2 O complexes.

Author

Lengyel J, Ončák M, Fedor J, Kočišek J, Pysanenko A, Beyer MK, and Fárník M

Abstract

Polar stratospheric clouds, which consist mainly of nitric acid containing ice particles, play a pivotal role in stratospheric chemistry. We investigate mixed nitric acid-water clusters (HNO 3 ) m (H 2 O) n , m ≈ 1-6, n ≈ 1-15, in a laboratory molecular beam experiment using electron attachment and mass spectrometry and interpret our experiments using DFT calculations. The reactions are triggered by the attachment of free electrons (0-14 eV) which leads to subsequent intracluster ion-molecule reactions. In these reactions, the nitrate anion NO 3 - turns out to play the central role. This contradicts the electron attachment to the gas-phase HNO 3 molecule, which leads almost exclusively to NO 2 - . The nitrate containing clusters are formed through at least three different reaction pathways and represent terminal product ions in the reaction cascade initiated by the electron attachment. Besides, the complex reaction pathways represent a new hitherto unrecognized source of atmospherically important OH and HONO molecules.

Published

2017

29. Clustering of Uracil Molecules on Ice Nanoparticles.

Author

Pysanenko A, Kočišek J, Nachtigallová D, Poterya V, and Fárník M

Abstract

We generate a molecular beam of ice nanoparticles (H 2 O) N , N̅ ≈ 130-220, which picks up several individual gas phase uracil (U) or 5-bromouracil (BrU) molecules. The mass spectra of the doped nanoparticles prove that the uracil and bromouracil molecules coagulate to clusters on the ice nanoparticles. Calculations of U and BrU monomers and dimers on the ice nanoparticles provide theoretical support for the cluster formation. The (U) m H + and (BrU) m H + intensity dependencies on m extracted from the mass spectra suggest a smaller tendency of BrU to coagulate compared to U, which is substantiated by a lower mobility of bromouracil on the ice surface. The hydrated U m ·(H 2 O) n H + series are also reported and discussed. On the basis of comparison with the previous experiments, we suggest that the observed propensity for aggregation on ice nanoparticles is a more general trend for biomolecules forming strong hydrogen bonds. This, together with their mobility, leads to their coagulation on ice nanoparticles which is an important aspect for astrochemistry.

Published

2017

30. Photodissociation dynamics of ethanethiol in clusters: complementary information from velocity map imaging, mass spectrometry and calculations.

Author

Svrčková P, Pysanenko A, Lengyel J, Rubovič P, Kočišek J, Poterya V, Slavíček P, and Fárník M

Abstract

We investigate the solvent effects on photodissociation dynamics of the S-H bond in ethanethiol CH3CH2SH (EtSH). The H fragment images are recorded by velocity map imaging (VMI) at 243 nm in various expansion regimes ranging from isolated molecules to clusters of different sizes and compositions. The VMI experiment is accompanied by electron ionization mass spectrometry using a reflectron time-of-flight mass spectrometer (RTOFMS). The experimental data are interpreted using ab initio calculations. The direct S-H bond fission results in a peak of fast fragments at Ekin(H) ≈ 1.25 eV with a partly resolved structure corresponding to vibrational levels of the CH3CH2S cofragment. Clusters of different nature ranging from dimers to large (EtSH)N, N ≥ 10, clusters and to ethanethiol clusters embedded in larger argon "snowballs" are investigated. In the clusters a sharp peak of near-zero kinetic energy fragments occurs due to the caging. The dynamics of the fragment caging is pictured theoretically, using multi-reference ab initio theory for the ethanethiol dimer. The larger cluster character is revealed by the simultaneous analysis of the VMI and RTOFMS experiments; none of these tools alone can provide the complete picture.

Published

2015

31. Clustering and photochemistry of freon CF2Cl2 on argon and ice nanoparticles.

Author

Poterya V, Kočišek J, Lengyel J, Svrčková P, Pysanenko A, Hollas D, Slavíček P, and Fárník M

Abstract

The photochemistry of CF2Cl2 molecules deposited on argon and ice nanoparticles was investigated. The clusters were characterized via electron ionization mass spectrometry, and the photochemistry was revealed by the Cl fragment velocity map imaging after the CF2Cl2 photodissociation at 193 nm. The complex molecular beam experiment was complemented by ab initio calculations. The (CF2Cl2)n clusters were generated in a coexpansion with Ar buffer gas. The photodissociation of molecules in the (CF2Cl2)n clusters yields predominantly Cl fragments with zero kinetic energy: caging. The CF2Cl2 molecules deposited on large argon clusters in a pickup experiment are highly mobile and coagulate to form the (CF2Cl2)n clusters on ArN. The photodissociation of the CF2Cl2 molecules and clusters on ArN leads to the caging of the Cl fragment. On the other hand, the CF2Cl2 molecules adsorbed on the (H2O)N ice nanoparticles do not form clusters, and no Cl fragments are observed from their photodissociation. Since the CF2Cl2 molecule was clearly adsorbed on (H2O)N, the missing Cl signal is interpreted in terms of surface orientation, possibly via the so-called halogen bond and/or embedding of the CF2Cl2 molecule on the disordered surface of the ice nanoparticles.

Published

2014

32. Caging of Cl atoms from photodissociation of CF2Cl2 in clusters.

Author

Poterya V, Kočišek J, Pysanenko A, and Fárník M

Abstract

We investigate the photodissociation dynamics of freon CF2Cl2 by velocity map imaging at 193 nm. The Cl fragment images are recorded in various expansion regimes corresponding to isolated molecules and molecules in rare gas clusters. The molecular kinetic energy distributions are dominated by a peak at Ekin(Cl) ≈ 0.97 eV corresponding to the direct C-Cl bond dissociation but they also reveal features at lower kinetic energies. Possible mechanisms leading to these slow Cl atoms are discussed. The photodissociation in clusters is investigated in two regimes: (i) small Ar clusters with the CF2Cl2 molecule embedded in approximately one solvation Ar layer; (ii) large Xen, n¯ ≈ 100-500, clusters with embedded CF2Cl2 molecules. In the former clusters we observe caging yielding the Cl fragments with zero kinetic energy and direct exit resulting in fragments with the kinetic energies corresponding to the fragments from isolated molecules. In the latter case (ii) only the caged Cl fragments are observed.

Published

2014

33. Nucleation of Mixed Nitric Acid-Water Ice Nanoparticles in Molecular Beams that Starts with a HNO3 Molecule.

Author

Lengyel J, Pysanenko A, Kočišek J, Poterya V, Pradzynski CC, Zeuch T, Slavíček P, and Fárník M

Abstract

Mixed (HNO3)m(H2O)n clusters generated in supersonic expansion of nitric acid vapor are investigated in two different experiments, (1) time-of-flight mass spectrometry after electron ionization and (2) Na doping and photoionization. This combination of complementary methods reveals that only clusters containing at least one acid molecule are generated, that is, the acid molecule serves as the nucleation center in the expansion. The experiments also suggest that at least four water molecules are needed for HNO3 acidic dissociation. The clusters are undoubtedly generated, as proved by electron ionization; however, they are not detected by the Na doping due to a fast charge-transfer reaction between the Na atom and HNO3. This points to limitations of the Na doping recently advocated as a general method for atmospheric aerosol detection. On the other hand, the combination of the two methods introduces a tool for detecting molecules with sizable electron affinity in clusters.

Published

2012