Your search keyword '"Ioppolo, Sergio"' showing total 141 results

1. Laboratory and Computational Studies of Interstellar Ices

Author

Cuppen, Herma M., Linnartz, Harold., and Ioppolo, Sergio

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Ice mantles play a crucial role in shaping the astrochemical inventory of molecules during star and planet formation. Small-scale molecular processes have a profound impact on large-scale astronomical evolution. The areas of solid-state laboratory astrophysics and computational chemistry study these processes. We review the laboratory effort on ice spectroscopy; methodological advances and challenges; and laboratory and computational studies of ice physics and ice chemistry. The latter we put in context with the ice evolution from clouds to disks. Three takeaway messages from this review are - Laboratory and computational studies allow interpretation of astronomical ice spectra in terms of identification, ice morphology and, local environmental conditions as well as the formation of the involved chemical compounds. - A detailed understanding of the underlying processes is needed to build reliable astrochemical models to make predictions on the abundances in space. - The relative importance of the different ice processes studied in the laboratory and computationally changes along the process of star and planet formation., Comment: 48 pages, 9 figures

Published

2024

2. Bombardment of CO ice by cosmic rays: I. Experimental insights into the microphysics of molecule destruction and sputtering

Author

Ivlev, Alexei V., Giuliano, Barbara M., Juhász, Zoltán, Herczku, Péter, Sulik, Béla, Mifsud, Duncan V., Kovács, Sándor T. S., Rahul, K. K., Rácz, Richárd, Biri, Sándor, Rajta, István, Vajda, István, Mason, Nigel J., Ioppolo, Sergio, and Caselli, Paola

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

We present a dedicated experimental study of microscopic mechanisms controlling radiolysis and sputtering of astrophysical ices due to their bombardment by cosmic ray ions. Such ions are slowed down due to inelastic collisions with bound electrons, resulting in ionization and excitation of ice molecules. In experiments on CO ice irradiation, we show that the relative contribution of these two mechanisms of energy loss to molecule destruction and sputtering can be probed by selecting ion energies near the peak of the electronic stopping power. We have observed a significant asymmetry, both in the destruction cross section and the sputtering yield, for pairs of ion energies corresponding to same values of the stopping power on either side of the peak. This implies that the stopping power does not solely control these processes, as usually assumed in the literature. Our results suggest that electronic excitations represent a significantly more efficient channel for radiolysis and, possibly, also for sputtering of CO ice. We also show that the charge state of incident ions as well as the rate for CO$^+$ production in the ice have negligible effect on these processes., Comment: Accepted for publication in ApJ

Published

2023

3. Proton and electron irradiations of CH4:H2O mixed ices

Author

Mifsud, Duncan V., Herczku, Péter, Sulik, Béla, Juhász, Zoltán, Vajda, István, Rajta, István, Ioppolo, Sergio, Mason, Nigel J., Strazzulla, Giovanni, and Kanuchová, Zuzana

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Earth and Planetary Astrophysics

Abstract

The organic chemistry occurring in interstellar environments may lead to the production of complex molecules that are relevant to the emergence of life. Therefore, in order to understand the origins of life itself, it is necessary to probe the chemistry of carbon-bearing molecules under conditions that simulate interstellar space. Several of these regions, such as dense molecular cores, are exposed to ionizing radiation in the form of galactic cosmic rays, which may act as an important driver of molecular destruction and synthesis. In this paper, we report the results of a comparative and systematic study of the irradiation of CH4:H2O ice mixtures by 1 MeV protons and 2 keV electrons at 20 K.We demonstrate that our irradiations result in the formation of a number of new products, including both simple and complex daughter molecules such as C2H6, C3H8, C2H2, CH3OH, CO, CO2, and probably also H2CO. A comparison of the different irradiation regimes has also revealed that proton irradiation resulted in a greater abundance of radiolytic daughter molecules compared to electron irradiation, despite a lower radiation dose having been administered. These results are important in the context of the radiation astrochemistry occurring within the molecular cores of dense interstellar clouds, as well as on outer Solar System objects., Comment: Published as an open access article in the MDPI journal Atoms

Published

2023

4. Contributors

Author

Akimkin, Vitaly, primary, Babb, James, additional, Bovino, Stefano, additional, Ercolano, Barbara, additional, Gaches, Brandt, additional, Galli, Daniele, additional, Grassi, Tommaso, additional, Haugbølle, Troels, additional, Holdship, Jonathan, additional, Ioppolo, Sergio, additional, Ivlev, Alexei, additional, Kamp, Inga, additional, Le Bourlot, Jacques, additional, Lupi, Alessandro, additional, Mifsud, Duncan V., additional, Padovani, Marco, additional, Rab, Christian, additional, Ramsey, Jon, additional, Reissl, Stefan, additional, Reynolds, Daniel R., additional, Richings, Alexander J., additional, Röllig, Markus, additional, Roueff, Evelyne, additional, Ruaud, Maxime, additional, Schleicher, Dominik, additional, Shingledecker, Christopher N., additional, Silsbee, Kedron, additional, Sipilä, Olli, additional, Viti, Serena, additional, Vogt-Geisse, Stefan, additional, and Wiebe, Dmitri, additional

Published

2024

5. Chemistry on interstellar dust grains

Author

Shingledecker, Christopher N., primary, Vogt-Geisse, Stefan, additional, Mifsud, Duncan V., additional, and Ioppolo, Sergio, additional

Published

2024

6. Energy transfer and restructuring in amorphous solid water upon consecutive irradiation

Author

Cuppen, Herma M., Noble, Jennifer A., Coussan, Stephane, Redlich, Britta, and Ioppolo, Sergio

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Chemical Physics

Abstract

Interstellar and cometary ices play an important role in the formation of planetary systems around young stars. Their main constituent is amorphous solid water (ASW). Although ASW is widely studied, vibrational energy dissipation and structural changes due to vibrational excitation are less well understood. The hydrogen-bonding network is likely a crucial component in this. Here we present experimental results on hydrogen-bonding changes in ASW induced by the intense, nearly monochromatic mid-IR free-electron laser (FEL) radiation of the FELIX-2 beamline at the HFML-FELIX facility at the Radboud University in Nijmegen, the Netherlands. Structural changes in ASW are monitored by reflection-absorption infrared spectroscopy and depend on the irradiation history of the ice. The experiments show that FEL irradiation can induce changes in the local neighborhood of the excited molecules due to energy transfer. Molecular Dynamics simulations confirm this picture: vibrationally excited molecules can reorient for a more optimal tetrahedral surrounding without breaking existing hydrogen bonds. The vibrational energy can transfer through the hydrogen-bonding network to water molecules that have the same vibrational frequency. We hence expect a reduced energy dissipation in amorphous material with respect to crystalline material due to the inhomogeneity in vibrational frequencies as well as the presence of specific hydrogen-bonding defect sites which can also hamper the energy transfer., Comment: 34 page, 9 figures

Published

2022

7. Energetic Electron Irradiations of Amorphous and Crystalline Sulphur-Bearing Astrochemical Ices

Author

Mifsud, Duncan V., Herczku, Péter, Rácz, Richárd, Rahul, K. K., Kovács, Sándor T. S., Juhász, Zoltán, Sulik, Béla, Biri, Sándor, McCullough, Robert W., Kaňuchová, Zuzana, Ioppolo, Sergio, Hailey, Perry A., and Mason, Nigel J.

Subjects

Physics - Chemical Physics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Astrophysics of Galaxies, Condensed Matter - Other Condensed Matter

Abstract

Laboratory experiments have confirmed that the radiolytic decay rate of astrochemical ice analogues is dependent upon the solid phase of the target ice, with some crystalline molecular ices being more radio-resistant than their amorphous counterparts. The degree of radio-resistance exhibited by crystalline ice phases is dependent upon the nature, strength, and extent of the intermolecular interactions that characterise their solid structure. For example, it has been shown that crystalline CH3OH decays at a significantly slower rate when irradiated by 2 keV electrons at 20 K than does the amorphous phase due to the stabilising effect imparted by the presence of an extensive array of strong hydrogen bonds. These results have important consequences for the astrochemistry of interstellar ices and outer Solar System bodies, as they imply that the chemical products arising from the irradiation of amorphous ices (which may include prebiotic molecules relevant to biology) should be more abundant than those arising from similar irradiations of crystalline phases. In this present study, we have extended our work on this subject by performing comparative energetic electron irradiations of the amorphous and crystalline phases of the sulphur-bearing molecules H2S and SO2 at 20 K. We have found evidence for phase-dependent chemistry in both these species, with the radiation-induced exponential decay of amorphous H2S being more rapid than that of the crystalline phase, similar to the effect that has been previously observed for CH3OH. For SO2, two fluence regimes are apparent: a low-fluence regime in which the crystalline ice exhibits a rapid exponential decay while the amorphous ice possibly resists decay, and a high-fluence regime in which both phases undergo slow exponential-like decays., Comment: Published in Frontiers in Chemistry (open access)

Published

2022

8. Ozone Production in Electron Irradiated CO2:O2 Ices

Author

Mifsud, Duncan V., Kaňuchová, Zuzana, Ioppolo, Sergio, Herczku, Péter, Muiña, Alejandra Traspas, Sulik, Béla, Rahul, K. K., Kovács, Sándor T. S., Hailey, Perry A., McCullough, Robert W., Mason, Nigel J., and Juhász, Zoltán

Subjects

Astrophysics - Earth and Planetary Astrophysics, Condensed Matter - Other Condensed Matter

Abstract

The detection of ozone (O3) in the surface ices of Ganymede, Jupiters largest moon, and of the Saturnian moons Rhea and Dione, has motivated several studies on the route of formation of this species. Previous studies have successfully quantified trends in the production of O3 as a result of the irradiation of pure molecular ices using ultraviolet photons and charged particles (i.e., ions and electrons), such as the abundances of O3 formed after irradiation at different temperatures or using different charged particles. In this study, we extend such results by quantifying the abundance of O3 as a result of the 1 keV electron irradiation of a series of 14 stoichiometrically distinct CO2:O2 astrophysical ice analogues at 20 K. By using mid-infrared spectroscopy as our primary analytical tool, we have also been able to perform a spectral analysis of the asymmetric stretching mode of solid O3 and the variation in its observed shape and profile among the investigated ice mixtures. Our results are important in the context of better understanding the surface composition and chemistry of icy outer Solar System objects, and may thus be of use to future interplanetary space missions such as the ESA Jupiter Icy Moons Explorer and the NASA Europa Clipper missions, as well as the recently launched NASA James Webb Space Telescope., Comment: Accepted for publication in Phys. Chem. Chem. Phys

Published

2022

9. Laboratory Experiments on the Radiation Astrochemistry of Water Ice Phases

Author

Mifsud, Duncan V., Hailey, Perry A., Herczku, Péter, Juhász, Zoltán, Kovács, Sándor T. S., Sulik, Béla, Ioppolo, Sergio, Kaňuchová, Zuzana, McCullough, Robert W., Paripás, Béla, and Mason, Nigel J.

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, Condensed Matter - Other Condensed Matter

Abstract

Water (H2O) ice is ubiquitous component of the universe, having been detected in a variety of interstellar and Solar System environments where radiation plays an important role in its physico-chemical transformations. Although the radiation chemistry of H2O astrophysical ice analogues has been well studied, direct and systematic comparisons of different solid phases are scarce and are typically limited to just two phases. In this article, we describe the results of an in-depth study of the 2 keV electron irradiation of amorphous solid water (ASW), restrained amorphous ice (RAI) and the cubic (Ic) and hexagonal (Ih) crystalline phases at 20 K so as to further uncover any potential dependence of the radiation physics and chemistry on the solid phase of the ice. Mid-infrared spectroscopic analysis of the four investigated H2O ice phases revealed that electron irradiation of the RAI, Ic, and Ih phases resulted in their amorphization (with the latter undergoing the process more slowly) while ASW underwent compaction. The abundance of hydrogen peroxide (H2O2) produced as a result of the irradiation was also found to vary between phases, with yields being highest in irradiated ASW. This observation is the cumulative result of several factors including the increased porosity and quantity of lattice defects in ASW, as well as its less extensive hydrogen-bonding network. Our results have astrophysical implications, particularly with regards to H2O-rich icy interstellar and Solar System bodies exposed to both radiation fields and temperature gradients., Comment: Published in the European Physical Journal D: Atomic, Molecular, Optical, and Plasma Physics

Published

2022

10. First experimental confirmation of the CH3O + H2CO -> CH3OH + HCO reaction: expanding the CH3OH formation mechanism in interstellar ices

Author

Santos, Julia C., Chuang, Ko-Ju, Lamberts, Thanja, Fedoseev, Gleb, Ioppolo, Sergio, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

The successive addition of H atoms to CO in the solid phase has been hitherto regarded as the primary route to form methanol in dark molecular clouds. However, recent Monte Carlo simulations of interstellar ices alternatively suggested the radical-molecule H-atom abstraction reaction CH3O + H2CO -> CH3OH + HCO, in addition to CH3O + H -> CH3OH, as a very promising and possibly dominating (70 - 90 %) final step to form CH3OH in those environments. Here, we compare the contributions of these two steps leading to methanol by experimentally investigating hydrogenation reactions on H2CO and D2CO ices, which ensures comparable starting points between the two scenarios. The experiments are performed under ultrahigh vacuum conditions and astronomically relevant temperatures, with H:H2CO (or D2CO) flux ratios of 10:1 and 30:1. The radical-molecule route in the partially deuterated scenario, CHD2O + D2CO -> CHD2OD + DCO, is significantly hampered by the isotope effect in the D-abstraction process, and can thus be used as an artifice to probe the efficiency of this step. We observe a significantly smaller yield of D2CO + H products in comparison to H2CO + H, implying that the CH3O-induced abstraction route must play an important role in the formation of methanol in interstellar ices. Reflection-Absorption InfraRed Spectroscopy (RAIRS) and Temperature Programmed Desorption-Quadrupole Mass Spectrometry (TPD-QMS) analyses are used to quantify the species in the ice. Both analytical techniques indicate constant contributions of ~80 % for the abstraction route in the 10 - 16 K interval, which agrees well with the Monte Carlo conclusions. Additional H2CO + D experiments confirm these conclusions., Comment: 10 pages, 1 table, 6 figures. Accepted in the Astrophysical Journal Letters

Published

2022

11. Comparative Electron Irradiations of Amorphous and Crystalline Astrophysical Ice Analogues

Author

Mifsud, Duncan V., Hailey, Perry A., Herczku, Péter, Sulik, Béla, Juhász, Zoltán, Kovács, Sándor T. S., Kaňuchová, Zuzana, Ioppolo, Sergio, McCullough, Robert W., Paripás, Béla, and Mason, Nigel J.

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics - Instrumentation and Methods for Astrophysics, Condensed Matter - Other Condensed Matter

Abstract

Laboratory studies of the radiation chemistry occurring in astrophysical ices have demonstrated the dependence of this chemistry on a number of experimental parameters. One experimental parameter which has received significantly less attention is that of the phase of the solid ice under investigation. In this present study, we have performed systematic 2 keV electron irradiations of the amorphous and crystalline phases of pure CH3OH and N2O astrophysical ice analogues. Radiation-induced decay of these ices and the concomitant formation of products were monitored in situ using FT-IR spectroscopy. A direct comparison between the irradiated amorphous and crystalline CH3OH ices revealed a more rapid decay of the former compared to the latter. Interestingly, a significantly lesser difference was observed when comparing the decay rates of the amorphous and crystalline N2O ices. These observations have been rationalised in terms of the strength and extent of the intermolecular forces present in each ice. The strong and extensive hydrogen-bonding network that exists in crystalline CH3OH (but not in the amorphous phase) is suggested to significantly stabilise this phase against radiation-induced decay. Conversely, although alignment of the dipole moment of N2O is anticipated to be more extensive in the crystalline structure, its weak attractive potential does not significantly stabilise the crystalline phase against radiation-induced decay, hence explaining the smaller difference in decay rates between the amorphous and crystalline phases of N2O compared to those of CH3OH. Our results are relevant to the astrochemistry of interstellar ices and icy Solar System objects, which may experience phase changes due to thermally-induced crystallisation or space radiation-induced amorphisation., Comment: Manuscript contains 18 pages, 6 figures, and 2 tables. Published as an advance article in PCCP

Published

2022

12. Infrared free-electron laser irradiation of carbon dioxide ice

Author

Ioppolo, Sergio, Noble, Jennifer A., Muiña, Alejandra Traspas, Cuppen, Herma M., Coussan, Stéphane, and Redlich, Britta

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

Interstellar ice grains are believed to play a key role in the formation of many of the simple and complex organic species detected in space. However, many fundamental questions on the physicochemical processes linked to the formation and survival of species in ice grains remain unanswered. Field work at large-scale facilities such as free-electron lasers (FELs) can aid the investigation of the composition and morphology of ice grains by providing novel tools to the laboratory astrophysics community. We combined the high tunability, wide infrared spectral range and intensity of the FEL beam line FELIX-2 at the HFML-FELIX Laboratory in the Netherlands with the characteristics of the ultrahigh vacuum LISA end station to perform wavelength-dependent mid-IR irradiation experiments of space-relevant pure carbon dioxide (CO2) ice at 20 K. We used the intense monochromatic radiation of FELIX to inject vibrational energy at selected frequencies into the CO2 ice to study ice restructuring effects in situ by Fourier Transform Reflection-Absorption Infrared (FT-RAIR) spectroscopy. This work improves our understanding of how vibrational energy introduced by external triggers such as photons, electrons, cosmic rays, and thermal heating coming from a nascent protostar or field stars is dissipated in an interstellar icy dust grain in space. Moreover, it adds to the current literature debate concerning the amorphous and polycrystalline structure of CO2 ice observed upon deposition at low temperatures, showing that, under our experimental conditions, CO2 ice presents amorphous characteristics when deposited at 20 K and is unambiguously crystalline if deposited at 75 K., Comment: Published in the 'Journal of Molecular Spectroscopy'. Includes 11 pages, 7 figures

Published

2022

13. Methoxymethanol Formation Starting from CO-Hydrogenation

Author

He, Jiao, Simons, Mart, Fedoseev, Gleb, Chuang, Ko-Ju, Qasim, Danna, Lamberts, Thanja, Ioppolo, Sergio, McGuire, Brett A., Cuppen, Herma, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Solar and Stellar Astrophysics

Abstract

Methoxymethanol (CH3OCH2OH, MM) has been identified through gas-phase signatures in both high- and low-mass star-forming regions. This molecule is expected to form upon hydrogen addition and abstraction reactions in CO-rich ice through radical recombination of CO hydrogenation products. The goal of this work is to investigate experimentally and theoretically the most likely solid-state MM reaction channel -- the recombination of CH2OH and CH3O radicals -- for dark interstellar cloud conditions and to compare the formation efficiency with that of other species that were shown to form along the CO-hydrogenation line. Hydrogen atoms and CO or H2CO molecules are co-deposited on top of the predeposited H2O ice to mimic the conditions associated with the beginning of 'rapid' CO freeze-out. Quadrupole mass spectrometry is used to analyze the gas-phase COM composition following a temperature programmed desorption. Monte Carlo simulations are used for an astrochemical model comparing the MM formation efficiency with that of other COMs. Unambiguous detection of newly formed MM has been possible both in CO+H and H2CO+H experiments. The resulting abundance of MM with respect to CH3OH is about 0.05, which is about 6 times less than the value observed toward NGC 6334I and about 3 times less than the value reported for IRAS 16293B. The results of astrochemical simulations predict a similar value for the MM abundance with respect to CH3OH factors ranging between 0.06 to 0.03. We find that MM is formed by co-deposition of CO and H2CO with H atoms through the recombination of CH2OH and CH3O radicals. In both the experimental and modeling studies, the efficiency of this channel alone is not sufficient to explain the observed abundance of MM. These results indicate an incomplete knowledge of the reaction network or the presence of alternative solid-state or gas-phase formation mechanisms., Comment: 8 pages, 8 figures

Published

2021

14. Hydrogenation of accreting C-atoms and CO molecules -- simulating ketene and acetaldehyde formation under dark and translucent cloud conditions

Author

Fedoseev, Gleb, Qasim, Danna, Chuang, Ko-Ju, Ioppolo, Sergio, Lamberts, Thanja, van Dishoeck, Ewine F., and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

Simple and complex organic molecules (COMs) are observed along different phases of star and planet formation and have been successfully identified in prestellar environments such as dark and translucent clouds. Yet the picture of organic molecule formation at those earliest stages of star formation is not complete and an important reason is the lack of specific laboratory experiments that simulate carbon atom addition reactions on icy surfaces of interstellar grains. Here we present experiments in which CO molecules as well as C- and H-atoms are co-deposited with H$_2$O molecules on a 10 K surface mimicking the ongoing formation of an "H$_2$O-rich" ice mantle. To simulate the effect of impacting C-atoms and resulting surface reactions with ice components, a specialized C-atom beam source is used, implemented on SURFRESIDE$^3$, an UHV cryogenic setup. Formation of ketene (CH$_2$CO) in the solid state is observed "in situ" by means of reflection absorption IR spectroscopy. C$^1$$^8$O and D isotope labelled experiments are performed to further validate the formation of ketene. Data analysis supports that CH$_2$CO is formed through C-atom addition to a CO-molecule, followed by successive hydrogenation transferring the formed :CCO into ketene. Efficient formation of ketene is in line with the absence of an activation barrier in C+CO reaction reported in the literature. We also discuss and provide experimental evidence for the formation of acetaldehyde (CH$_3$CHO) and possible formation of ethanol (CH$_3$CH$_2$OH), two COM derivatives of CH$_2$CO hydrogenation. The underlying reaction network is presented and the astrochemical implications of the derived pathways are discussed., Comment: Accepted by ApJ

Published

2021

15. A systematic mid-infrared spectroscopic study of thermally processed H2S ices

Author

Mifsud, Duncan V., Herczku, Péter, Ramachandran, Ragav, Sundararajan, Pavithraa, Rahul, K.K., Kovács, Sándor T.S., Sulik, Béla, Juhász, Zoltán, Rácz, Richárd, Biri, Sándor, Kaňuchová, Zuzana, Ioppolo, Sergio, Sivaraman, Bhalamurugan, McCullough, Robert W., and Mason, Nigel J.

Published

2024

16. Electron Irradiation and Thermal Chemistry Studies of Interstellar and Planetary Ice Analogues at the ICA Astrochemistry Facility

Author

Mifsud, Duncan V., Juhász, Zoltán, Herczku, Péter, Kovács, Sándor T. S., Ioppolo, Sergio, Kanuchová, Zuzana, Czentye, Máté, Hailey, Perry A., Muina, Alejandra Traspas, Mason, Nigel J., McCullough, Robert W., Paripás, Béla, and Sulik, Béla

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

The modelling of molecular excitation and dissociation processes relevant to astrochemistry requires the validation of theories by comparison with data generated from laboratory experimentation. The newly commissioned Ice Chamber for Astrophysics-Astrochemistry (ICA) allows for the study of astrophysical ice analogues and their evolution when subjected to energetic processing, thus simulating the processes and alterations interstellar icy grain mantles and icy outer Solar System bodies undergo. ICA is an ultra-high vacuum compatible chamber containing a series of IR-transparent substrates upon which the ice analogues may be deposited at temperatures of down to 20 K. Processing of the ices may be performed in one of three ways: (i) ion impacts with projectiles delivered by a 2 MV Tandetron-type accelerator, (ii) electron irradiation from a gun fitted directly to the chamber, and (iii) thermal processing across a temperature range of 20-300 K. The physico-chemical evolution of the ices is studied in situ using FTIR absorbance spectroscopy and quadrupole mass spectrometry. In this paper, we present an overview of the ICA facility with a focus on characterising the electron beams used for electron impact studies, as well as reporting the preliminary results obtained during electron irradiation and thermal processing of selected ices., Comment: Published in European Physical Journal Part D: Atomic, Molecular, Optical, and Plasma Physics

Published

2021

17. The Ice Chamber for Astrophysics-Astrochemistry (ICA): A New Experimental Facility for Ion Impact Studies of Astrophysical Ice Analogues

Author

Herczku, Péter, Mifsud, Duncan V., Ioppolo, Sergio, Juhász, Zoltán, Kanuchová, Zuzana, Kovács, Sándor T. S., Muina, Alejandra Traspas, Hailey, Perry A., Rajta, István, Vajda, István, Mason, Nigel J., McCullough, Robert W., Paripás, Béla, and Sulik, Béla

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

The Ice Chamber for Astrophysics-Astrochemistry (ICA) is a new laboratory end-station located at the Institute for Nuclear Research (Atomki) in Debrecen, Hungary. The ICA has been specifically designed for the study of the physico-chemical properties of astrophysical ice analogues and their chemical evolution when subjected to ionising radiation and thermal processing. The ICA is an ultra-high vacuum compatible chamber containing a series of IR-transparent substrates mounted in a copper holder connected to a closed-cycle cryostat capable of being cooled down to 20 K, itself mounted on a 360{\deg} rotation stage and a z-linear manipulator. Ices are deposited onto the substrates via background deposition of dosed gases. Ice structure and chemical composition are monitored by means of FTIR absorbance spectroscopy in transmission mode, although use of reflectance mode is possible by using metallic substrates. Pre-prepared ices may be processed in a variety of ways. A 2 MV Tandetron accelerator is capable of delivering a wide variety of high-energy ions into the ICA, which simulates ice processing by cosmic rays, the solar wind, or magnetospheric ions. The ICA is also equipped with an electron gun which may be used for electron impact radiolysis of ices. Thermal processing of both deposited and processed ices may be monitored by means of both FTIR spectroscopy and quadrupole mass spectrometry. In this paper, we provide a detailed description of the ICA set-up, as well as an overview of preliminary results obtained and future plans., Comment: Published in Review of Scientific Instruments

Published

2021

18. The Role of Terahertz and Far-IR Spectroscopy in Understanding the Formation and Evolution of Interstellar Prebiotic Molecules

Author

Mifsud, Duncan V., Hailey, Perry A., Muina, Alejandra Traspas, Auriacombe, Olivier, Ioppolo, Sergio, and Mason, Nigel J.

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Stellar systems are often formed through the collapse of dense molecular clouds which, in turn, return copious amounts of atomic and molecular material to the interstellar medium. An in-depth understanding of chemical evolution during this cyclic interaction between the stars and the interstellar medium is at the heart of astrochemistry. Systematic chemical composition changes as interstellar clouds evolve from the diffuse stage to dense, quiescent molecular clouds to star-forming regions and proto-planetary disks further enrich the molecular diversity leading to the evolution of ever more complex molecules. In particular, the icy mantles formed on interstellar dust grains and their irradiation are thought to be the origin of many of the observed molecules, including those that are deemed to be prebiotic; that is those molecules necessary for the origin of life. This review will discuss both observational (e.g., ALMA, SOFIA, Herschel) and laboratory investigations using millimeter, submillimeter, and terahertz and far-IR (THz/F-IR) spectroscopies and the role that they play in contributing to our understanding of the formation of prebiotic molecules. Mid-IR spectroscopy has typically been the primary tool used in laboratory studies. However, THz/F-IR spectroscopy offers an additional and complementary approach in that it provides the ability to investigate intermolecular interactions compared to the intramolecular modes available in the mid-IR. THz/F-IR spectroscopy is still somewhat under-utilized, but with the additional capability it brings, its popularity is likely to significantly increase in the near future. This review will discuss the strengths and limitations of such methods, and will also provide some suggestions on future research areas that should be pursued in the coming decade exploiting both space-borne and laboratory facilities., Comment: Submitted for publication in Frontiers in Astronomy and Space Science

Published

2021

19. Sulphur ion implantation into O2, CO, and CO2 ices: Implications for the formation of sulphur-bearing molecules in the Kuiper Belt

Author

Mifsud, Duncan V., Kaňuchová, Zuzana, Herczku, Péter, Juhász, Zoltán, Kovács, Sándor T.S., Lakatos, Gergő, Rahul, K.K., Rácz, Richárd, Sulik, Béla, Biri, Sándor, Rajta, István, Vajda, István, Ioppolo, Sergio, McCullough, Robert W., and Mason, Nigel J.

Published

2024

20. Sulfur Ice Astrochemistry: A Review of Laboratory Studies

Author

Mifsud, Duncan V., Kanuchova, Zuzana, Herczku, Peter, Ioppolo, Sergio, Juhasz, Zoltan, Kovacs, Sandor T. S., Mason, Nigel J., McCullough, Robert W., and Sulik, Bela

Subjects

Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Sulfur is the tenth most abundant element in the universe and is known to play a significant role in biological systems. Accordingly, in recent years there has been increased interest in the role of sulfur in astrochemical reactions and planetary geology and geochemistry. Among the many avenues of research currently being explored is the laboratory processing of astrophysical ice analogues. Such research involves the synthesis of an ice of specific morphology and chemical composition at temperatures and pressures relevant to a selected astrophysical setting (such as the interstellar medium or the surfaces of icy moons). Subsequent processing of the ice under conditions that simulate the selected astrophysical setting commonly involves radiolysis, photolysis, thermal processing, neutral-neutral fragment chemistry, or any combination of these, and has been the subject of several studies. The in-situ changes in ice morphology and chemistry occurring during such processing has been monitored via spectroscopic or spectrometric techniques. In this paper, we have reviewed the results of laboratory investigations concerned with sulfur chemistry in several astrophysical ice analogues. Specifically, we review (i) the spectroscopy of sulfur-containing astrochemical molecules in the condensed phase, (ii) atom and radical addition reactions, (iii) the thermal processing of sulfur-bearing ices, (iv) photochemical experiments, (v) the non-reactive charged particle radiolysis of sulfur-bearing ices, and (vi) sulfur ion bombardment of and implantation in ice analogues. Potential future studies in the field of solid phase sulfur astrochemistry are also discussed in the context of forthcoming space missions, such as the NASA James Webb Space Telescope and the ESA Jupiter Icy Moons Explorer mission., Comment: Peer-reviewed version accepted for publication in Space Science Reviews

Published

2021

21. A Systematic Study on the Absorption Features of Interstellar Ices in Presence of Impurities

Author

Gorai, Prasanta, Sil, Milan, Das, Ankan, Sivaraman, Bhalamurugan, Chakrabarti, Sandip K., Ioppolo, Sergio, Puzzarini, Cristina, Kanuchova, Zuzana, Dawes, Anita, Mendolicchio, Marco, Mancini, Giordano, Barone, Vincenzo, Nakatani, Naoki, Shimonishi, Takashi, and Mason, Nigel

Subjects

Astrophysics - Astrophysics of Galaxies, Physics - Chemical Physics

Abstract

Spectroscopic studies play a key role in the identification and analysis of interstellar ices and their structure. Some molecules have been identified within the interstellar ices either as pure, mixed, or even as layered structures. Absorption band features of water ice can significantly change with the presence of different types of impurities (CO, CO2, CH3OH, H2CO, etc.). In this work, we carried out a theoretical investigation to understand the behavior of water band frequency, and strength in the presence of impurities. The computational study has been supported and complemented by some infrared spectroscopy experiments aimed at verifying the effect of HCOOH, NH3 , and CH3 OH on the band profiles of pure H2O ice. Specifically, we explored the effect on the band strength of libration, bending, bulk stretching, and free-OH stretching modes. Computed band strength profiles have been compared with our new and existing experimental results, thus pointing out that vibrational modes of H2O and their intensities can change considerably in the presence of impurities at different concentrations. In most cases, the bulk stretching mode is the most affected vibration, while the bending is the least affected mode. HCOOH was found to have a strong influence on the libration, bending, and bulk stretching band profiles. In the case of NH3, the free-OH stretching band disappears when the impurity concentration becomes 50%. This work will ultimately aid a correct interpretation of future detailed spaceborne observations of interstellar ices by means of the upcoming JWST mission., Comment: Accepted for Publication in the ACS Earth and Space Chemistry Journal

Published

2020

22. Searches for Interstellar HCCSH and H$_2$CCS

Author

McGuire, Brett A., Shingledecker, Christopher N., Willis, Eric R., Lee, Kin Long Kelvin, Martin-Drumel, Marie-Aline, Blake, Geoffrey A., Brogan, Crystal L., Burkhardt, Andrew M., Caselli, Paola, Chuang, Ko-Ju, El-Abd, Samer, Hunter, Todd R., Ioppolo, Sergio, Linnartz, Harold, Remijan, Anthony J., Xue, Ci, and McCarthy, Michael C.

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

A long standing problem in astrochemistry is the inability of many current models to account for missing sulfur content. Many relatively simple species that may be good candidates to sequester sulfur have not been measured experimentally at the high spectral resolution necessary to enable radioastronomical identification. On the basis of new laboratory data, we report searches for the rotational lines in the microwave, millimeter, and sub-millimeter regions of the sulfur-containing hydrocarbon HCCSH. This simple species would appear to be a promising candidate for detection in space owing to the large dipole moment along its $b$-inertial axis, and because the bimolecular reaction between two highly abundant astronomical fragments (CCH and SH radicals) may be rapid. An inspection of multiple line surveys from the centimeter to the far-infrared toward a range of sources from dark clouds to high-mass star-forming regions, however, resulted in non-detections. An analogous search for the lowest-energy isomer, H$_2$CCS, is presented for comparison, and also resulted in non-detections. Typical upper limits on the abundance of both species relative to hydrogen are $10^{-9}$-$10^{-10}$. We thus conclude that neither isomer is a major reservoir of interstellar sulfur in the range of environments studied. Both species may still be viable candidates for detection in other environments or at higher frequencies, providing laboratory frequencies are available., Comment: Accepted in the Astrophysical Journal

Published

2019

23. Formation of Glycerol through Hydrogenation of CO ice under Prestellar Core Conditions

Author

Fedoseev, Gleb, Chuang, Ko-Ju, Ioppolo, Sergio, Qasim, Danna, van Dishoeck, Ewine F., and Linnartz, Harold

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

Observational studies reveal that complex organic molecules (COMs) can be found in various objects associated with different star formation stages. The identification of COMs in prestellar cores, i.e., cold environments in which thermally induced chemistry can be excluded and radiolysis is limited by cosmic rays and cosmic ray induced UV-photons, is particularly important as this stage sets up the initial chemical composition from which ultimately stars and planets evolve. Recent laboratory results demonstrate that molecules as complex as glycolaldehyde and ethylene glycol are efficiently formed on icy dust grains via non-energetic atom addition reactions between accreting H atoms and CO molecules, a process that dominates surface chemistry during the 'CO-freeze out stage' in dense cores. In the present study we demonstrate that a similar mechanism results in the formation of the biologically relevant molecule glycerol - HOCH2CH(OH)CH2OH - a three-carbon bearing sugar alcohol necessary for the formation of membranes of modern living cells and organelles. Our experimental results are fully consistent with a suggested reaction scheme in which glycerol is formed along a chain of radical-radical and radical-molecule interactions between various reactive intermediates produced upon hydrogenation of CO ice or its hydrogenation products. The tentative identification of the chemically related simple sugar glyceraldehyde - HOCH2CH(OH)CHO - is discussed as well. These new laboratory findings indicate that the proposed reaction mechanism holds much potential to form even more complex sugar alcohols and simple sugars., Comment: Accepted for publication in The Astrophysical Journal

Published

2017

24. Experimental evidence for Glycolaldehyde and Ethylene Glycol formation by surface hydrogenation of CO molecules under dense molecular cloud conditions

Author

Fedoseev, Gleb, Cuppen, Herma M., Ioppolo, Sergio, Lamberts, Thanja, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

This study focuses on the formation of two molecules of astrobiological importance - glycolaldehyde (HC(O)CH2OH) and ethylene glycol (H2C(OH)CH2OH) - by surface hydrogenation of CO molecules. Our experiments aim at simulating the CO freeze-out stage in interstellar dark cloud regions, well before thermal and energetic processing become dominant. It is shown that along with the formation of H2CO and CH3OH - two well established products of CO hydrogenation - also molecules with more than one carbon atom form. The key step in this process is believed to be the recombination of two HCO radicals followed by the formation of a C-C bond. The experimentally established reaction pathways are implemented into a continuous-time random-walk Monte Carlo model, previously used to model the formation of CH3OH on astrochemical time-scales, to study their impact on the solid-state abundances in dense interstellar clouds of glycolaldehyde and ethylene glycol.

Published

2017

25. Deuterium enrichment of ammonia produced by surface N+H/D addition reactions at low temperature

Author

Fedoseev, Gleb, Ioppolo, Sergio, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

The surface formation of NH3 and its deuterated isotopologues - NH2D, NHD2, and ND3 - is investigated at low temperatures through the simultaneous addition of hydrogen and deuterium atoms to nitrogen atoms in CO-rich interstellar ice analogues. The formation of all four ammonia isotopologues is only observed up to 15 K, and drops below the detection limit for higher temperatures. Differences between hydrogenation and deuteration yields result in a clear deviation from a statistical distribution in favour of deuterium enriched species. The data analysis suggests that this is due to a higher sticking probability of D atoms to the cold surface, a property that may generally apply to molecules that are formed in low temperature surface reactions. The results found here are used to interpret ammonia deuterium fractionation as observed in pre-protostellar cores.

Published

2017

26. Low Temperature Surface Formation of NH3 and HNCO: hydrogenation of nitrogen atoms in CO-rich interstellar ice analogues

Author

Fedoseev, Gleb, Ioppolo, Sergio, Zhao, Dongfeng, Lamberts, Thanja, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

Solid state astrochemical reaction pathways have the potential to link the formation of small nitrogen-bearing species, like NH3 and HNCO, and prebiotic molecules, specifically amino acids. To date, the chemical origin of such small nitrogen containing species is still not well understood, despite the fact that ammonia is an abundant constituent of interstellar ices toward young stellar objects and quiescent molecular clouds. This is mainly because of the lack of dedicated laboratory studies. The aim of the present work is to experimentally investigate the formation routes of NH3 and HNCO through non-energetic surface reactions in interstellar ice analogues under fully controlled laboratory conditions and at astrochemically relevant temperatures. This study focuses on the formation of NH3 and HNCO in CO-rich (non-polar) interstellar ices that simulate the CO freeze-out stage in dark interstellar cloud regions, well before thermal and energetic processing start to become relevant. We demonstrate and discuss the surface formation of solid HNCO through the interaction of CO molecules with NH radicals - one of the intermediates in the formation of solid NH3 upon sequential hydrogenation of N atoms. The importance of HNCO for astrobiology is discussed.

Published

2017

27. Efficient Surface Formation Route of Interstellar Hydroxylamine through NO Hydrogenation II: the multilayer regime in interstellar relevant ices

Author

Fedoseev, Gleb, Ioppolo, Sergio, Lamberts, Thanja, Zhen, Junfeng, Cuppen, Herma M., and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

Hydroxylamine (NH2OH) is one of the potential precursors of complex pre-biotic species in space. Here we present a detailed experimental study of hydroxylamine formation through nitric oxide (NO) surface hydrogenation for astronomically relevant conditions. The aim of this work is to investigate hydroxylamine formation efficiencies in polar (water-rich) and non-polar (carbon monoxide-rich) interstellar ice analogues. A complex reaction network involving both final (N2O, NH2OH) and intermediate (HNO, NH2O, etc.) products is discussed. The main conclusion is that hydroxylamine formation takes place via a fast and barrierless mechanism and it is found to be even more abundantly formed in a water-rich environment at lower temperatures. In parallel, we experimentally verify the non-formation of hydroxylamine upon UV photolysis of NO ice at cryogenic temperatures as well as the non-detection of NC- and NCO-bond bearing species after UV processing of NO in carbon monoxide-rich ices. Our results are implemented into an astrochemical reaction model, which shows that NH2OH is abundant in the solid phase under dark molecular cloud conditions. Once NH2OH desorbs from the ice grains, it becomes available to form more complex species (e.g., glycine and beta-alanine) in gas phase reaction schemes.

Published

2017

28. Simultaneous Hydrogenation and UV-photolysis Experiments of NO in CO-rich Interstellar Ice Analogues; linking HNCO, OCN-, NH2CHO and NH2OH

Author

Fedoseev, Gleb, Chuang, Ko-Ju, van Dishoeck, Ewine F., Ioppolo, Sergio, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

The laboratory work presented here, simulates the chemistry on icy dust grains as typical for the 'CO freeze-out stage' in dark molecular clouds. It differs from previous studies in that solid-state hydrogenation and vacuum UV-photoprocessing are applied simultaneously to co-depositing molecules. In parallel, the reactions at play are described for fully characterized laboratory conditions. The focus is on the formation of molecules containing both carbon and nitrogen atoms, starting with NO in CO-, H2CO-, and CH3OH-rich ices at 13 K. The experiments yield three important conclusions. 1. Without UV-processing hydroxylamine (NH2OH) is formed, as reported previously. 2. With UV-processing (energetic) NH2 is formed through photodissociation of NH2OH. This radical is key in the formation of species with an N-C bond. 3. The formation of three N-C bearing species, HNCO, OCN- and NH2CHO is observed. The experiments put a clear chemical link between these species; OCN- is found to be a direct derivative of HNCO and the latter is shown to have the same precursor as formamide (NH2CHO). Moreover, the addition of VUV competing channels decreases the amount of NO molecules converted into NH2OH by at least one order of magnitude. Consequently, this decrease in NH2OH formation yield directly influences the amount of NO molecules that can be converted into HNCO, OCN- and NH2CHO.

Published

2017

29. Importance of tunneling in H-abstraction reactions by OH radicals: The case of CH4 + OH studied through isotope-substituted analogs

Author

Lamberts, Thanja, Fedoseev, Gleb, Kästner, Johannes, Ioppolo, Sergio, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics, Physics - Chemical Physics

Abstract

We present a combined experimental and theoretical study focussing on the quantum tunneling of atoms in the reaction between CH4 and OH. The importance of this reaction pathway is derived by investigating isotope substituted analogs. Quantitative reaction rates needed for astrochemical models at low temperature are currently unavailable both in the solid state and in the gas phase. Here, we study tunneling effects upon hydrogen abstraction in CH4 + OH by focusing on two reactions: CH4 + OD -> CH3 + HDO and CD4 + OH -> CD3 + HDO. The experimental study shows that the solid-state reaction rate R(CH4 + OD) is higher than R(CD4 + OH) at 15 K. Experimental results are accompanied by calculations of the corresponding unimolecular and bimolecular reaction rate constants using instanton theory taking into account surface effects. From the work presented here, the unimolecular reactions are particularly interesting as these provide insight into reactions following a Langmuir-Hinshelwood process. The resulting ratio of the rate constants shows that the H abstraction (k(CH4 + OD)) is approximately ten times faster than D-abstraction (k(CD4 + OH)) at 65 K. We conclude that tunneling is involved at low temperatures in the abstraction reactions studied here. The unimolecular rate constants can be used by the modeling community as a first approach to describe OH-mediated abstraction reactions in the solid phase. For this reason we provide fits of our calculated rate constants that allow the inclusion of these reactions in models in a straightforward fashion., Comment: Accepted by A&A

Published

2016

30. THz Time-Domain Spectroscopy of Mixed CO2-CH3OH Interstellar Ice Analogs

Author

McGuire, Brett A., Ioppolo, Sergio, Allodi, Marco A., and Blake, Geoffrey A.

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

The icy mantles of interstellar dust grains are the birthplaces of the primordial prebiotic molecular inventory that may eventually seed nascent solar systems and the planets and planetesimals that form therein. Here, we present a study of two of the most abundant species in these ices after water: carbon dioxide (CO2) and methanol (CH3OH) using TeraHertz (THz) time-domain spectroscopy and mid-infrared spectroscopy. We study pure and mixed-ices of these species, and demonstrate the power of the THz region of the spectrum to elucidate the long-range structure (i.e. crystalline versus amorphous) of the ice, the degree of segregation of these species within the ice, and the thermal history of the species within the ice. Finally, we comment on the utility of the THz transitions arising from these ices for use in astronomical observations of interstellar ices., Comment: Accepted for publication in Physical Chemistry Chemical Physics

Published

2016

31. Atom addition reactions in interstellar ice analogues

Author

Linnartz, Harold, Ioppolo, Sergio, and Fedoseev, Gleb

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

This review paper summarizes the state-of-the-art in laboratory based interstellar ice chemistry. The focus is on atom addition reactions, illustrating how water, carbon dioxide and methanol can form in the solid state at astronomically relevant temperatures, and also the formation of more complex species such as hydroxylamine, an important prebiotic molecule, and glycolaldehyde, the smallest sugar, is discussed. These reactions are particularly relevant during the dark ages of star and planet formation, i.e., when the role of UV light is restricted. A quantitative characterization of such processes is only possible through dedicated laboratory studies, i.e., under full control of a large set of parameters such as temperature, atom-flux, and ice morphology. The resulting numbers, physical and chemical constants, e.g., barrier heights, reaction rates and branching ratios, provide information on the molecular processes at work and are needed as input for astrochemical models, in order to bridge the timescales typical for a laboratory setting to those needed to understand the evolutionary stages of the interstellar medium. Details of the experiments as well as the astrochemical impact of the results are discussed.

Published

2015

32. Thermal H/D exchange in polar ice - deuteron scrambling in space

Author

Lamberts, Thanja, Ioppolo, Sergio, Cuppen, Herma, Fedoseev, Gleb, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

We have investigated the thermally induced proton/deuteron exchange in mixed amorphous H$_2$O:D$_2$O ices by monitoring the change in intensity of characteristic vibrational bending modes of H$_2$O, HDO, and D$_2$O with time and as function of temperature. The experiments have been performed using an ultra-high vacuum setup equipped with an infrared spectrometer that is used to investigate the spectral evolution of homogeneously mixed ice upon co-deposition in thin films, for temperatures in the 90 to 140 K domain. With this non-energetic detection method we find a significantly lower activation energy for H/D exchange -- $3840 \pm 125$ K -- than previously reported. Very likely this is due to the amorphous nature of the interstellar ice analogues involved. This provides reactive timescales ($\tau<10^4$ years at $T$ $>70$ K) fast enough for the process to be important in interstellar environments. Consequently, an astronomical detection of D$_2$O will be even more challenging because of its potential to react with H$_2$O to form HDO. Furthermore, additional experiments, along with previous studies, show that proton/deuteron swapping also occurs in ice mixtures of water with other hydrogen bonded molecules, in particular on the OH and NH moieties. We conclude that H/D exchange in ices is a more general process that should be incorporated into ice models that are applied to protoplanetary disks or to simulate the warming up of cometary ices in their passage of the perihelion, to examine the extent of its influence on the final deuteron over hydrogen ratio., Comment: 10 pages, 8 figures, accepted for publication in MNRAS

Published

2015

33. Infrared Spectral Signatures of Nucleobases in Interstellar Ices I: Purines

Author

Rosa, Caroline Antunes, primary, Bergantini, Alexandre, additional, Herczku, Péter, additional, Mifsud, Duncan V., additional, Lakatos, Gergő, additional, Kovács, Sándor T. S., additional, Sulik, Béla, additional, Juhász, Zoltán, additional, Ioppolo, Sergio, additional, Quitián-Lara, Heidy M., additional, Mason, Nigel J., additional, and Lage, Claudia, additional

Published

2023

34. On the relevance of the H2 + O reaction pathway for the surface formation of interstellar water - A combined experimental and modeling study

Author

Lamberts, Thanja, Cuppen, Herma, Fedoseev, Gleb, Ioppolo, Sergio, Chuang, Ko-Ju, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, Physics - Chemical Physics

Abstract

The formation of interstellar water has been commonly accepted to occur on the surfaces of icy dust grains in dark molecular clouds at low temperatures (10-20 K), involving hydrogenation reactions of oxygen allotropes. As a result of the large abundances of molecular hydrogen and atomic oxygen in these regions, the reaction H2 + O has been proposed to contribute significantly to the formation of water as well. However, gas phase experiments and calculations, as well as solid-phase experimental work contradict this hypothesis. Here, we use precisely executed temperature programmed desorption (TPD) experiments in an ultra-high vacuum setup combined with kinetic Monte Carlo simulations to establish an upper limit of the water production starting from H2 and O. These reactants are brought together in a matrix of CO2 in a series of (control) experiments at different temperatures and with different isotopological compositions. The amount of water detected with the quadrupole mass spectrometer upon TPD is found to originate mainly from contamination in the chamber itself. However, if water is produced in small quantities on the surface through H2 + O, this can only be explained by a combined classical and tunneled reaction mechanism. An absolutely conservative upper limit for the reaction rate is derived with a microscopic kinetic Monte Carlo model that converts the upper limit into a maximal possible reaction rate. Incorporating this rate into simulations run for astrochemically relevant parameters, shows that the upper limit to the contribution of the reaction H2 + O in OH, and hence water formation, is 11% in dense interstellar clouds. Our combined experimental and theoretical results indicate however, that this contribution is likely to be much lower., Comment: 9 pages, 4 figures

Published

2014

35. Chapter 4 - Chemistry on interstellar dust grains

Author

Shingledecker, Christopher N., Vogt-Geisse, Stefan, Mifsud, Duncan V., and Ioppolo, Sergio

Published

2024

36. LABORATORY ICE ASTROCHEMISTRY IN THE ERA OF JWST

Author

Ioppolo, Sergio, primary

Published

2023

37. A systematic mid-infrared spectroscopic study of thermally processed SO2 ices.

Author

Mifsud, Duncan V., Herczku, Péter, Rahul, K. K., Ramachandran, Ragav, Sundararajan, Pavithraa, Kovács, Sándor T. S., Sulik, Béla, Juhász, Zoltán, Rácz, Richárd, Biri, Sándor, Kaňuchová, Zuzana, McCullough, Robert W., Sivaraman, Bhalamurugan, Ioppolo, Sergio, and Mason, Nigel J.

Abstract

The use of mid-infrared spectroscopy to characterise the chemistry of icy interstellar and Solar System environments will be exploited in the near future to better understand the chemical processes and molecular inventories in various astronomical environments. This is, in part, due to observational work made possible by the recently launched James Webb Space Telescope as well as forthcoming missions to the outer Solar System that will observe in the mid-infrared spectroscopic region (e.g., the Jupiter Icy Moons Explorer and the Europa Clipper missions). However, such spectroscopic characterisations are crucially reliant upon the generation of laboratory data for comparative purposes. In this paper, we present an extensive mid-infrared characterisation of SO2 ice condensed at several cryogenic temperatures between 20 and 100 K and thermally annealed to sublimation in an ultrahigh-vacuum system. Our results are anticipated to be useful in confirming the detection (and possibly thermal history) of SO2 on various Solar System bodies, such as Ceres and the icy Galilean moons of Jupiter, as well as in interstellar icy grain mantles. [ABSTRACT FROM AUTHOR]

Published

2023

38. Bombardment of CO Ice by Cosmic Rays. I. Experimental Insights into the Microphysics of Molecule Destruction and Sputtering

Author

Ivlev, Alexei V., primary, Giuliano, Barbara M., additional, Juhász, Zoltán, additional, Herczku, Péter, additional, Sulik, Béla, additional, Mifsud, Duncan V., additional, Kovács, Sándor T. S., additional, Rahul, K. K., additional, Rácz, Richárd, additional, Biri, Sándor, additional, Rajta, István, additional, Vajda, István, additional, Mason, Nigel J., additional, Ioppolo, Sergio, additional, and Caselli, Paola, additional

Published

2023

39. Proton and Electron Irradiations of CH4:H2O Mixed Ices

Author

Mifsud, Duncan V., primary, Herczku, Péter, additional, Sulik, Béla, additional, Juhász, Zoltán, additional, Vajda, István, additional, Rajta, István, additional, Ioppolo, Sergio, additional, Mason, Nigel J., additional, Strazzulla, Giovanni, additional, and Kaňuchová, Zuzana, additional

Published

2023

40. Infrared photodesorption of CO from astrophysically relevant ices studied with a free-electron laser

Author

Ingman, Emily R., primary, Laurinavicius, Domantas, additional, Zhang, Jin, additional, Schrauwen, Johanna G. M., additional, Redlich, Britta, additional, Noble, Jennifer A., additional, Ioppolo, Sergio, additional, McCoustra, Martin R. S., additional, and Brown, Wendy A., additional

Published

2023

41. A systematic mid-infrared spectroscopic study of thermally processed SO2 ices

Author

Mifsud, Duncan V., primary, Herczku, Péter, additional, Rahul, K. K., additional, Ramachandran, Ragav, additional, Sundararajan, Pavithraa, additional, Kovács, Sándor T. S., additional, Sulik, Béla, additional, Juhász, Zoltán, additional, Rácz, Richárd, additional, Biri, Sándor, additional, Kaňuchová, Zuzana, additional, McCullough, Robert W., additional, Sivaraman, Bhalamurugan, additional, Ioppolo, Sergio, additional, and Mason, Nigel J., additional

Published

2023

42. Energy Transfer and Restructuring in Amorphous Solid Water upon Consecutive Irradiation

Author

Cuppen, Herma M., primary, Noble, Jennifer A., additional, Coussan, Stephane, additional, Redlich, Britta, additional, and Ioppolo, Sergio, additional

Published

2022

43. Energetic electron irradiations of amorphous and crystalline sulphur-bearing astrochemical ices

Author

Mifsud, Duncan V., primary, Herczku, Péter, additional, Rácz, Richárd, additional, Rahul, K. K., additional, Kovács, Sándor T. S., additional, Juhász, Zoltán, additional, Sulik, Béla, additional, Biri, Sándor, additional, McCullough, Robert W., additional, Kaňuchová, Zuzana, additional, Ioppolo, Sergio, additional, Hailey, Perry A., additional, and Mason, Nigel J., additional

Published

2022

44. Astrochemistry Experimental Setup at Atomki-ECRIS: A Europlanet Facility

Author

Kushwaha, Rahul K, primary, Rácz, Richárd, additional, Kovács, Sándor T S, additional, Herczku, Péter, additional, Sulik, Béla, additional, Juhász, Zoltán, additional, Biri, Sándor, additional, Mifsud, Duncan V, additional, Ioppolo, Sergio, additional, Kanuchová, Zuzana, additional, Field, Thomas A, additional, Hailey, Perry, additional, McCullough, Robert, additional, and Mason, Nigel J, additional

Published

2022

45. The Effect of the Solid Phase Adopted by Astrophysical Ices on their Radiation Chemistry and Physics: Implications for the Synthesis of Prebiotic Molecules

Author

Mifsud, Duncan, primary, Hailey, Perry, additional, Herczku, Péter, additional, Juhász, Zoltán, additional, Kovács, Sándor, additional, Sulik, Béla, additional, Kumar Kushwaha, Rahul, additional, Rácz, Richard, additional, Biri, Sándor, additional, Ioppolo, Sergio, additional, Kaňuchová, Zuzana, additional, Paripás, Béla, additional, McCullough, Robert, additional, and Mason, Nigel, additional

Published

2022

46. First Experimental Confirmation of the CH3O + H2CO → CH3OH + HCO Reaction: Expanding the CH3OH Formation Mechanism in Interstellar Ices

Author

Santos, Julia C., primary, Chuang, Ko-Ju, additional, Lamberts, Thanja, additional, Fedoseev, Gleb, additional, Ioppolo, Sergio, additional, and Linnartz, Harold, additional

Published

2022

47. Laboratory experiments on the radiation astrochemistry of water ice phases

Author

Mifsud, Duncan V., primary, Hailey, Perry A., additional, Herczku, Péter, additional, Juhász, Zoltán, additional, Kovács, Sándor T. S., additional, Sulik, Béla, additional, Ioppolo, Sergio, additional, Kaňuchová, Zuzana, additional, McCullough, Robert W., additional, Paripás, Béla, additional, and Mason, Nigel J., additional

Published

2022

48. Proton and Electron Irradiations of CH 4 :H 2 O Mixed Ices.

Author

Mifsud, Duncan V., Herczku, Péter, Sulik, Béla, Juhász, Zoltán, Vajda, István, Rajta, István, Ioppolo, Sergio, Mason, Nigel J., Strazzulla, Giovanni, and Kaňuchová, Zuzana

Subjects

IRRADIATION, GALACTIC cosmic rays, IONIZING radiation, COSMIC rays, PROTONS, ORGANIC chemistry, SOLAR system, ELECTRONS

Abstract

The organic chemistry occurring in interstellar environments may lead to the production of complex molecules that are relevant to the emergence of life. Therefore, in order to understand the origins of life itself, it is necessary to probe the chemistry of carbon-bearing molecules under conditions that simulate interstellar space. Several of these regions, such as dense molecular cores, are exposed to ionizing radiation in the form of galactic cosmic rays, which may act as an important driver of molecular destruction and synthesis. In this paper, we report the results of a comparative and systematic study of the irradiation of CH4:H2O ice mixtures by 1 MeV protons and 2 keV electrons at 20 K. We demonstrate that our irradiations result in the formation of a number of new products, including both simple and complex daughter molecules such as C2H6, C3H8, C2H2, CH3OH, CO, CO2, and probably also H2CO. A comparison of the different irradiation regimes has also revealed that proton irradiation resulted in a greater abundance of radiolytic daughter molecules compared to electron irradiation, despite a lower radiation dose having been administered. These results are important in the context of the radiation astrochemistry occurring within the molecular cores of dense interstellar clouds, as well as on outer Solar System objects. [ABSTRACT FROM AUTHOR]

Published

2023

49. IRFEL Selective Irradiation of Amorphous Solid Water: from Dangling to Bulk Modes

Author

Coussan, Stephane, primary, Noble, Jennifer A., additional, Cuppen, Herma M., additional, Redlich, Britta, additional, and Ioppolo, Sergio, additional

Published

2022

50. Infrared free-electron laser irradiation of carbon dioxide ice

Author

Ioppolo, Sergio, primary, Noble, Jennifer A., additional, Traspas Muiña, Alejandra, additional, Cuppen, Herma M., additional, Coussan, Stéphane, additional, and Redlich, Britta, additional

Published

2022