Your search keyword '"Boduch, P."' showing total 30 results

1. Cosmic ray sputtering yield of interstellar ice mantles: CO and CO2 ice thickness dependence

Author

Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Boduch, P., Augé, B., Agnihotri, A. N., Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Boduch, P., Augé, B., and Agnihotri, A. N.

Abstract

Cosmic-ray-induced sputtering is one of the important desorption mechanisms at work in astrophysical environments. The chemical evolution observed in high-density regions, from dense clouds to protoplanetary disks, and the release of species condensed on dust grains, is one key parameter to be taken into account in interpretations of both observations and models. This study is part of an ongoing systematic experimental determination of the parameters to consider in astrophysical cosmic ray sputtering. As was already done for water ice, we investigated the sputtering yield as a function of ice mantle thickness for the two next most abundant species of ice mantles, carbon monoxide and carbon dioxide, which were exposed to several ion beams to explore the dependence with deposited energy. These ice sputtering yields are constant for thick films. It decreases rapidly for thin ice films when reaching the impinging ion sputtering desorption depth. An ice mantle thickness dependence constraint can be implemented in the astrophysical modelling of the sputtering process, in particular close to the onset of ice mantle formation at low visual extinctions., Comment: To appear in Astronomy & Astrophysics

Published

2021

2. Non-thermal desorption of complex organic molecules: Cosmic-ray sputtering of CH3OH embedded in CO2 ice

Author

Dartois, E., Chabot, M., Bacmann, A., Boduch, P., Domaracka, A., Rothard, H., Dartois, E., Chabot, M., Bacmann, A., Boduch, P., Domaracka, A., and Rothard, H.

Abstract

Methanol ice is embedded in interstellar ice mantles present in dense molecular clouds. We aim to measure the sputtering efficiencies starting from different ice mantles of varying compositions experimentally, in order to evaluate their potential impact on astrochemical models. The sputtering yields of complex organic molecules is of particular interest, since few mechanisms are efficient enough to induce a significant feedback to the gas phase. We irradiated methanol and carbon dioxide ice mixtures of varying ratios with swift heavy ions in the electronic sputtering regime. We monitored the evolution of the infrared spectra and the species released to the gas phase with a mass spectrometer. Methanol and 13C-methanol isotopologue were used to remove any ambiguity on the measured irradiation products. The sputtering of methanol embedded in carbon dioxide ice is an efficient process leading to the ejection of intact methanol in the gas phase. We establish that when methanol is embedded in a carbon-dioxide-rich mantle exposed to cosmic rays, a significant fraction is sputtered as intact molecules. The sputtered fraction follows the time-dependent bulk composition of the ice mantle, the latter evolving with time due to the radiolysis-induced evolution of the bulk. If methanol is embedded in a carbon dioxide ice matrix, as the analyses of the spectral shape of the CO2 bending mode observations in some lines of sight suggest, the overall methanol sputtering yield is higher than if embedded in a water ice mantle. The sputtering is increased by a factor close to the dominant ice matrix sputtering yield, which is about six times higher for pure carbon dioxide ice when compared to water ice. These experiments are further constraining the cosmic-ray-induced ice mantle sputtering mechanisms important role in the gas-phase release of complex organic molecules from the interstellar solid phase., Comment: arXiv admin note: text overlap with arXiv:1906.03084

Published

2020

3. Non-thermal desorption of complex organic molecules: Cosmic-ray sputtering of CH3OH embedded in CO2 ice

Author

Dartois, E., Chabot, M., Bacmann, A., Boduch, P., Domaracka, A., Rothard, H., Dartois, E., Chabot, M., Bacmann, A., Boduch, P., Domaracka, A., and Rothard, H.

Abstract

Methanol ice is embedded in interstellar ice mantles present in dense molecular clouds. We aim to measure the sputtering efficiencies starting from different ice mantles of varying compositions experimentally, in order to evaluate their potential impact on astrochemical models. The sputtering yields of complex organic molecules is of particular interest, since few mechanisms are efficient enough to induce a significant feedback to the gas phase. We irradiated methanol and carbon dioxide ice mixtures of varying ratios with swift heavy ions in the electronic sputtering regime. We monitored the evolution of the infrared spectra and the species released to the gas phase with a mass spectrometer. Methanol and 13C-methanol isotopologue were used to remove any ambiguity on the measured irradiation products. The sputtering of methanol embedded in carbon dioxide ice is an efficient process leading to the ejection of intact methanol in the gas phase. We establish that when methanol is embedded in a carbon-dioxide-rich mantle exposed to cosmic rays, a significant fraction is sputtered as intact molecules. The sputtered fraction follows the time-dependent bulk composition of the ice mantle, the latter evolving with time due to the radiolysis-induced evolution of the bulk. If methanol is embedded in a carbon dioxide ice matrix, as the analyses of the spectral shape of the CO2 bending mode observations in some lines of sight suggest, the overall methanol sputtering yield is higher than if embedded in a water ice mantle. The sputtering is increased by a factor close to the dominant ice matrix sputtering yield, which is about six times higher for pure carbon dioxide ice when compared to water ice. These experiments are further constraining the cosmic-ray-induced ice mantle sputtering mechanisms important role in the gas-phase release of complex organic molecules from the interstellar solid phase., Comment: arXiv admin note: text overlap with arXiv:1906.03084

Published

2020

4. Processing of 72-K water-rich ices by keV and MeV oxygen ions:implications for the Saturnian moon Enceladus

Author

Rachid, M. G., Pilling, S., Rocha, W. R. M., Agnihotri, A., Rothard, H., Boduch, P., Rachid, M. G., Pilling, S., Rocha, W. R. M., Agnihotri, A., Rothard, H., and Boduch, P.

Published

2020

5. Infrared complex refractive index of N-containing astrophysical ices free of water processed by cosmic-ray simulated in laboratory

Author

Rocha, W. R. M., Pilling, S., Domaracka, A., Rothard, H., Boduch, P., Rocha, W. R. M., Pilling, S., Domaracka, A., Rothard, H., and Boduch, P.

Published

2020

6. Infrared complex refractive index of N-containing astrophysical ices free of water processed by cosmic-ray simulated in laboratory

Author

Rocha, W. R. M., Pilling, S., Domaracka, A., Rothard, H., Boduch, P., Rocha, W. R. M., Pilling, S., Domaracka, A., Rothard, H., and Boduch, P.

Published

2020

7. Processing of 72-K water-rich ices by keV and MeV oxygen ions:implications for the Saturnian moon Enceladus

Author

Rachid, M. G., Pilling, S., Rocha, W. R. M., Agnihotri, A., Rothard, H., Boduch, P., Rachid, M. G., Pilling, S., Rocha, W. R. M., Agnihotri, A., Rothard, H., and Boduch, P.

Published

2020

8. Non-thermal desorption of complex organic molecules

Author

Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Augé, B., Agnihotri, A. N., Domaracka, A., Boduch, P., Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Augé, B., Agnihotri, A. N., Domaracka, A., and Boduch, P.

Abstract

The occurrence of complex organic molecules (COMs) in the gas phase at low temperature in the dense phases of the ISM suggests that a non-thermal desorption mechanism is at work because otherwise, COMs should condense within a short timescale onto dust grains. Vacuum ultraviolet photodesorption has been shown to be much less efficient for complex organic molecules, such as methanol, because mostly photoproducts are ejected. The induced photolysis competes with photodesorption for large COMs, considerably lowering the efficiency to desorb intact molecules. We investigate the sputtering efficiency of complex organic molecules that are observed either in the ice mantles of interstellar dense clouds directly by infrared spectroscopy (CH3OH), or that are observed in the gas phase by millimeter telescopes (CH3COOCH3) and that could be released from interstellar grain surfaces. We irradiated ice films containing complex organic molecules (methanol and methyl acetate) and water with swift heavy ions in the electronic sputtering regime. We monitored the infrared spectra of the film as well as the species released to the gas phase with a mass spectrometer. We demonstrate that when methanol or methyl acetate is embedded in a water-ice mantle exposed to cosmic rays, a large portion is sputtered as an intact molecule, with a sputtering yield close to that of the main water-ice matrix. This must be even more true for more volatile ice matrices, such as those that are embedded in carbon monoxide. Cosmic rays penetrating deep into dense clouds provide an efficient mechanism to desorb complex organic molecules. Compared to VUV photons induced by the interaction of cosmic rays, a large portion desorb as intact molecules with a proportion corresponding to the time-dependent bulk composition of the ice mantle, the latter evolving with time as a function of fluence due to the radiolysis of the bulk., Comment: Corrected a copy/paste typo in Table 2: The CO2 stretch A value is 7.6d-17 Gerakines et al. (1995), replacing 1.8d-17 D'Hendecourt & Allamandola (1986)

Published

2019

9. Roadmap on photonic, electronic and atomic collision physics: III. Heavy particles: with zero to relativistic speeds

Author

Aumayr, F., Ueda, K., Sokell, E., Schippers, S., Sadeghpour, H., Merkt, F., Gallagher, T. F., Dunning, F. B., Scheier, P., Echt, O., Kirchner, T., Fritzsche, S., Surzhykov, A., Ma, X., Rivarola, R., Fojon, O., Tribedi, L., Lamour, E., Crespo López-Urrutia, J. R., Litvinov, Y. A., Shabaev, V., Cederquist, H., Zettergren, H., Schleberger, M., (0000-0001-9451-5440) Wilhelm, R. A., Azuma, T., Boduch, P., Schmidt, H. T., Stöhlker, T., Aumayr, F., Ueda, K., Sokell, E., Schippers, S., Sadeghpour, H., Merkt, F., Gallagher, T. F., Dunning, F. B., Scheier, P., Echt, O., Kirchner, T., Fritzsche, S., Surzhykov, A., Ma, X., Rivarola, R., Fojon, O., Tribedi, L., Lamour, E., Crespo López-Urrutia, J. R., Litvinov, Y. A., Shabaev, V., Cederquist, H., Zettergren, H., Schleberger, M., (0000-0001-9451-5440) Wilhelm, R. A., Azuma, T., Boduch, P., Schmidt, H. T., and Stöhlker, T.

Abstract

We publish three Roadmaps on photonic, electronic and atomic collision physics in order to celebrate the 60th anniversary of the ICPEAC conference. Roadmap III focusses on heavy particles: with zero to relativistic speeds. Modern theoretical and experimental approaches provide detailed insight into the wide range of many-body interactions involving projectiles and targets of varying complexity ranging from simple atoms, through molecules and clusters, complex biomolecules and nanoparticles to surfaces and crystals. These developments have been driven by technological progress and future developments will expand the horizon of the systems that can be studied. This Roadmap aims at looking back along the road, explaining the evolution of the field, and looking forward, collecting nineteen contributions from leading scientists in the field.

Published

2019

10. Non-thermal desorption of complex organic molecules

Author

Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Augé, B., Agnihotri, A. N., Domaracka, A., Boduch, P., Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Augé, B., Agnihotri, A. N., Domaracka, A., and Boduch, P.

Abstract

The occurrence of complex organic molecules (COMs) in the gas phase at low temperature in the dense phases of the ISM suggests that a non-thermal desorption mechanism is at work because otherwise, COMs should condense within a short timescale onto dust grains. Vacuum ultraviolet photodesorption has been shown to be much less efficient for complex organic molecules, such as methanol, because mostly photoproducts are ejected. The induced photolysis competes with photodesorption for large COMs, considerably lowering the efficiency to desorb intact molecules. We investigate the sputtering efficiency of complex organic molecules that are observed either in the ice mantles of interstellar dense clouds directly by infrared spectroscopy (CH3OH), or that are observed in the gas phase by millimeter telescopes (CH3COOCH3) and that could be released from interstellar grain surfaces. We irradiated ice films containing complex organic molecules (methanol and methyl acetate) and water with swift heavy ions in the electronic sputtering regime. We monitored the infrared spectra of the film as well as the species released to the gas phase with a mass spectrometer. We demonstrate that when methanol or methyl acetate is embedded in a water-ice mantle exposed to cosmic rays, a large portion is sputtered as an intact molecule, with a sputtering yield close to that of the main water-ice matrix. This must be even more true for more volatile ice matrices, such as those that are embedded in carbon monoxide. Cosmic rays penetrating deep into dense clouds provide an efficient mechanism to desorb complex organic molecules. Compared to VUV photons induced by the interaction of cosmic rays, a large portion desorb as intact molecules with a proportion corresponding to the time-dependent bulk composition of the ice mantle, the latter evolving with time as a function of fluence due to the radiolysis of the bulk., Comment: Corrected a copy/paste typo in Table 2: The CO2 stretch A value is 7.6d-17 Gerakines et al. (1995), replacing 1.8d-17 D'Hendecourt & Allamandola (1986)

Published

2019

11. Cosmic ray sputtering yield of interstellar H2O ice mantles : Ice mantle thickness dependence

Author

Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Augé, B., Agnihotri, A. N., Domaracka, A., Boduch, P., Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Augé, B., Agnihotri, A. N., Domaracka, A., and Boduch, P.

Abstract

Interstellar grain mantles present in dense interstellar clouds are in constant exchange with the gas phase via accretion and desorption mechanisms such as UV, X-ray photodesorption, cosmic ray induced sputtering, grain thermal fluctuations, and chemical reaction energy release. The relative importance of the various desorption mechanisms is of uttermost importance for astrophysical models to constrain the chemical evolution in such high density dense cloud regions. In this experimental work we investigated the sputtering yield as a function of ice mantle thickness, exposed to Xe ions at 95MeV. The ion induced ice phase transformation and the sputtering yield were simultaneously monitored by IR spectroscopy and mass spec- trometry, respectively. The sputtering yield is constant above a characteristic ice layer thickness and starts to decrease below this thickness. An estimate of the sputtering depth corresponding to this length can be evaluated. In these experiments the measured desorption depth corresponds to 30 ice layers. Assuming an effective cylindrical shape for the volume of sputtered molecules, the aspect ratio is close to unity; in the semi-infinite ice film case this ratio is the diameter to height of the cylinder. This result shows that most ejected molecules arise from a rather compact volume. The measured infinite thickness sputtering yield for water ice mantles scales as the square of the ion electronic stopping power (Se). We expect that the desorption depth dependence varies with Se^a , where a=0.5. Astrophysical models should take into account the thickness dependence constraints of these ice mantles in the interface regions when ices are close to their extinction threshold. In the very dense cloud regions, most of the water ice mantles are above this limit for the bulk of the cosmic rays., Comment: 6 pages, 5 figures

Published

2018

12. Cosmic ray sputtering yield of interstellar H2O ice mantles : Ice mantle thickness dependence

Author

Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Augé, B., Agnihotri, A. N., Domaracka, A., Boduch, P., Dartois, E., Chabot, M., Barkach, T. Id, Rothard, H., Augé, B., Agnihotri, A. N., Domaracka, A., and Boduch, P.

Abstract

Interstellar grain mantles present in dense interstellar clouds are in constant exchange with the gas phase via accretion and desorption mechanisms such as UV, X-ray photodesorption, cosmic ray induced sputtering, grain thermal fluctuations, and chemical reaction energy release. The relative importance of the various desorption mechanisms is of uttermost importance for astrophysical models to constrain the chemical evolution in such high density dense cloud regions. In this experimental work we investigated the sputtering yield as a function of ice mantle thickness, exposed to Xe ions at 95MeV. The ion induced ice phase transformation and the sputtering yield were simultaneously monitored by IR spectroscopy and mass spec- trometry, respectively. The sputtering yield is constant above a characteristic ice layer thickness and starts to decrease below this thickness. An estimate of the sputtering depth corresponding to this length can be evaluated. In these experiments the measured desorption depth corresponds to 30 ice layers. Assuming an effective cylindrical shape for the volume of sputtered molecules, the aspect ratio is close to unity; in the semi-infinite ice film case this ratio is the diameter to height of the cylinder. This result shows that most ejected molecules arise from a rather compact volume. The measured infinite thickness sputtering yield for water ice mantles scales as the square of the ion electronic stopping power (Se). We expect that the desorption depth dependence varies with Se^a , where a=0.5. Astrophysical models should take into account the thickness dependence constraints of these ice mantles in the interface regions when ices are close to their extinction threshold. In the very dense cloud regions, most of the water ice mantles are above this limit for the bulk of the cosmic rays., Comment: 6 pages, 5 figures

Published

2018

13. Chemical reactions in the nitrogen-acetone ice induced by cosmic ray analogs: relevance for the Solar System

Author

de Barros, A. L. F., Andrade, D. P. P., da Silveira, E. F., Alcantara, K. F., Boduch, P., Rothard, H., de Barros, A. L. F., Andrade, D. P. P., da Silveira, E. F., Alcantara, K. F., Boduch, P., and Rothard, H.

Abstract

The radiolysis of a nitrogen-acetone mixture, condensed at 11 K, by 40 MeV $^{58}$Ni$^{11+}$ ions is studied. These results are representative of studies concerning solar system objects exposed to cosmic rays. In the Kuiper Belt, region of Trans-Neptunian Objects (TNOs), acetone, molecular nitrogen and other small molecules were detected and may be present on icy surfaces. Bombardment by cosmic rays triggers chemical reactions leading to synthesis of larger molecules. In this work, destruction cross sections of acetone and nitrogen in solid phase are determined from a sequence of infrared spectra obtained at increasing ion beam fluence. The results are analyzed and compared with those of previous experiments performed with pure acetone. It is observed that the molecular nitrogen column density decrease very fast, suggesting that nitrogen quickly leaves a porous sample under irradiation. The behavior of acetone in the mixture confirms that the ice formed by deposition of vapor mixture is more porous than that of pure acetone ice. The most abundant molecular species formed from the mixture during irradiation are: C$_3$H$_6$, C$_2$H$_6$, N$_3$, CO, CH$_4$ and CO$_2$. Some N-bearing species are also formed, but with low production yield. Comparing with pure acetone results, it is seen that dissolving acetone in nitrogen affects the formation cross sections of the new species: CH$_4$, CO$_2$ and H$_2$CO, for example, have formation cross section smaller than the respective values for irradiated pure acetone, while those for CO and C$_2$H$_6$ species are higher. This fact can explain the presence of C$_2$H$_6$ even in regions on Pluto where CH$_4$ is not pure, but diluted in a N$_2$ matrix together with less abundant species. These results also show the formation of more complex molecules, such as HNCO, acetic acid and, possibility, glycine., Comment: 16 pages, 9 figures, 5 tables

Published

2017

14. Chemical reactions in the nitrogen-acetone ice induced by cosmic ray analogs: relevance for the Solar System

Author

de Barros, A. L. F., Andrade, D. P. P., da Silveira, E. F., Alcantara, K. F., Boduch, P., Rothard, H., de Barros, A. L. F., Andrade, D. P. P., da Silveira, E. F., Alcantara, K. F., Boduch, P., and Rothard, H.

Abstract

The radiolysis of a nitrogen-acetone mixture, condensed at 11 K, by 40 MeV $^{58}$Ni$^{11+}$ ions is studied. These results are representative of studies concerning solar system objects exposed to cosmic rays. In the Kuiper Belt, region of Trans-Neptunian Objects (TNOs), acetone, molecular nitrogen and other small molecules were detected and may be present on icy surfaces. Bombardment by cosmic rays triggers chemical reactions leading to synthesis of larger molecules. In this work, destruction cross sections of acetone and nitrogen in solid phase are determined from a sequence of infrared spectra obtained at increasing ion beam fluence. The results are analyzed and compared with those of previous experiments performed with pure acetone. It is observed that the molecular nitrogen column density decrease very fast, suggesting that nitrogen quickly leaves a porous sample under irradiation. The behavior of acetone in the mixture confirms that the ice formed by deposition of vapor mixture is more porous than that of pure acetone ice. The most abundant molecular species formed from the mixture during irradiation are: C$_3$H$_6$, C$_2$H$_6$, N$_3$, CO, CH$_4$ and CO$_2$. Some N-bearing species are also formed, but with low production yield. Comparing with pure acetone results, it is seen that dissolving acetone in nitrogen affects the formation cross sections of the new species: CH$_4$, CO$_2$ and H$_2$CO, for example, have formation cross section smaller than the respective values for irradiated pure acetone, while those for CO and C$_2$H$_6$ species are higher. This fact can explain the presence of C$_2$H$_6$ even in regions on Pluto where CH$_4$ is not pure, but diluted in a N$_2$ matrix together with less abundant species. These results also show the formation of more complex molecules, such as HNCO, acetic acid and, possibility, glycine., Comment: 16 pages, 9 figures, 5 tables

Published

2017

15. Infrared complex refractive index of astrophysical ices exposed to cosmic rays simulated in the laboratory

Author

Rocha, W. R. M., Pilling, S., de Barros, A. L. F., Andrade, D. P. P., Rothard, H., Boduch, P., Rocha, W. R. M., Pilling, S., de Barros, A. L. F., Andrade, D. P. P., Rothard, H., and Boduch, P.

Abstract

In dense and cold regions of the interstellar medium (ISM), molecules may be adsorbed onto dust grains to form the ice mantles. Once formed, they can be processed by ionizing radiation coming from stellar or interstellar medium leading to formation of several new molecules in the ice. Among the different kind of ionizing radiation, cosmic rays play an important role in the solid-phase chemistry because of the large amount of energy deposited in the ices. The physicochemical changes induced by the energetic processing of astrophysical ices are recorded in a intrinsic parameter of the matter called complex refractive index (CRI). In this paper, we present for the first time a catalogue containing 39 complex refractive indices (n, k) in the infrared from 2.0 - 16.6 micrometer for 13 different water-containing ices processed in laboratory by cosmic ray analogs. The calculation was done by using the NKABS (acronym of determination of N and K from ABSorbance data) code, which employs the Lambert-Beer and Kramers-Kronig equations to calculate the values of n and k. The results are also available at the website: http://www1.univap.br/gaa/nkabs-database/data.htm. As test case, a H2O:NH3:CO2:CH4 ice was employed in a radiative transfer simulation of a prototoplanetary disk to show that these data are indispensable to reproduce the spectrum of YSOs containing ices.

Published

2016

16. Infrared complex refractive index of astrophysical ices exposed to cosmic rays simulated in the laboratory

Author

Rocha, W. R. M., Pilling, S., de Barros, A. L. F., Andrade, D. P. P., Rothard, H., Boduch, P., Rocha, W. R. M., Pilling, S., de Barros, A. L. F., Andrade, D. P. P., Rothard, H., and Boduch, P.

Abstract

In dense and cold regions of the interstellar medium (ISM), molecules may be adsorbed onto dust grains to form the ice mantles. Once formed, they can be processed by ionizing radiation coming from stellar or interstellar medium leading to formation of several new molecules in the ice. Among the different kind of ionizing radiation, cosmic rays play an important role in the solid-phase chemistry because of the large amount of energy deposited in the ices. The physicochemical changes induced by the energetic processing of astrophysical ices are recorded in a intrinsic parameter of the matter called complex refractive index (CRI). In this paper, we present for the first time a catalogue containing 39 complex refractive indices (n, k) in the infrared from 2.0 - 16.6 micrometer for 13 different water-containing ices processed in laboratory by cosmic ray analogs. The calculation was done by using the NKABS (acronym of determination of N and K from ABSorbance data) code, which employs the Lambert-Beer and Kramers-Kronig equations to calculate the values of n and k. The results are also available at the website: http://www1.univap.br/gaa/nkabs-database/data.htm. As test case, a H2O:NH3:CO2:CH4 ice was employed in a radiative transfer simulation of a prototoplanetary disk to show that these data are indispensable to reproduce the spectrum of YSOs containing ices.

Published

2016

17. Heavy ion irradiation of crystalline water ice

Author

Dartois, E., Augé, B., Boduch, P., Brunetto, R., Chabot, M., Domaracka, A., Ding, J. J., Kamalou, O., Lv, X. Y., Rothard, H., da Silveira, E. F., Thomas, J. C., Dartois, E., Augé, B., Boduch, P., Brunetto, R., Chabot, M., Domaracka, A., Ding, J. J., Kamalou, O., Lv, X. Y., Rothard, H., da Silveira, E. F., and Thomas, J. C.

Abstract

Under cosmic irradiation, the interstellar water ice mantles evolve towards a compact amorphous state. Crystalline ice amorphisation was previously monitored mainly in the keV to hundreds of keV ion energies. We experimentally investigate heavy ion irradiation amorphisation of crystalline ice, at high energies closer to true cosmic rays, and explore the water-ice sputtering yield. We irradiated thin crystalline ice films with MeV to GeV swift ion beams, produced at the GANIL accelerator. The ice infrared spectral evolution as a function of fluence is monitored with in-situ infrared spectroscopy (induced amorphisation of the initial crystalline state into a compact amorphous phase). The crystalline ice amorphisation cross-section is measured in the high electronic stopping-power range for different temperatures. At large fluence, the ice sputtering is measured on the infrared spectra, and the fitted sputtering-yield dependence, combined with previous measurements, is quadratic over three decades of electronic stopping power. The final state of cosmic ray irradiation for porous amorphous and crystalline ice, as monitored by infrared spectroscopy, is the same, but with a large difference in cross-section, hence in time scale in an astrophysical context. The cosmic ray water-ice sputtering rates compete with the UV photodesorption yields reported in the literature. The prevalence of direct cosmic ray sputtering over cosmic-ray induced photons photodesorption may be particularly true for ices strongly bonded to the ice mantles surfaces, such as hydrogen-bonded ice structures or more generally the so-called polar ices., Comment: 22pages, 11 figures, accepted in A&A

Published

2015

18. Heavy ion irradiation of crystalline water ice

Author

Dartois, E., Augé, B., Boduch, P., Brunetto, R., Chabot, M., Domaracka, A., Ding, J. J., Kamalou, O., Lv, X. Y., Rothard, H., da Silveira, E. F., Thomas, J. C., Dartois, E., Augé, B., Boduch, P., Brunetto, R., Chabot, M., Domaracka, A., Ding, J. J., Kamalou, O., Lv, X. Y., Rothard, H., da Silveira, E. F., and Thomas, J. C.

Abstract

Under cosmic irradiation, the interstellar water ice mantles evolve towards a compact amorphous state. Crystalline ice amorphisation was previously monitored mainly in the keV to hundreds of keV ion energies. We experimentally investigate heavy ion irradiation amorphisation of crystalline ice, at high energies closer to true cosmic rays, and explore the water-ice sputtering yield. We irradiated thin crystalline ice films with MeV to GeV swift ion beams, produced at the GANIL accelerator. The ice infrared spectral evolution as a function of fluence is monitored with in-situ infrared spectroscopy (induced amorphisation of the initial crystalline state into a compact amorphous phase). The crystalline ice amorphisation cross-section is measured in the high electronic stopping-power range for different temperatures. At large fluence, the ice sputtering is measured on the infrared spectra, and the fitted sputtering-yield dependence, combined with previous measurements, is quadratic over three decades of electronic stopping power. The final state of cosmic ray irradiation for porous amorphous and crystalline ice, as monitored by infrared spectroscopy, is the same, but with a large difference in cross-section, hence in time scale in an astrophysical context. The cosmic ray water-ice sputtering rates compete with the UV photodesorption yields reported in the literature. The prevalence of direct cosmic ray sputtering over cosmic-ray induced photons photodesorption may be particularly true for ices strongly bonded to the ice mantles surfaces, such as hydrogen-bonded ice structures or more generally the so-called polar ices., Comment: 22pages, 11 figures, accepted in A&A

Published

2015

19. Processing of formic acid-containing ice by heavy and energetic cosmic ray analogues

Author

Bergantini, A., Pilling, S., Rothard, H., Boduch, P., Andrade, D. P. P., Bergantini, A., Pilling, S., Rothard, H., Boduch, P., and Andrade, D. P. P.

Abstract

Formic acid (HCOOH) has been extensively detected in space environments, including interstellar medium (gas and grains), comets and meteorites. Such environments are often subjected to the action of ionizing agents, which may cause changes in the molecular structure, thus leading to formation of new species. Formic acid is a possible precursor of pre-biotic species, such as Glycine (NH2CH2COOH). This work investigates experimentally the physicochemical effects resulting from interaction of heavy and energetic cosmic ray analogues (46MeV 58Ni11+) in H2O:HCOOH (1:1) ice, at 15 K, in ultrahigh vacuum regime, using Fourier transform infrared spectrometry in the mid-infrared region (4000-600 cm-1 or 2.5-12.5 microns). After the bombardment, the sample was slowly heated to room temperature. The results show the dissociation cross-section for the formic acid of 2.4x10^-13 cm2, and half-life due to galactic cosmic rays of 8x10^7 yr. The IR spectra show intense formation of CO and CO2, and small production of more complex species at high fluences.

Published

2014

20. Comparison of UV and high-energy ion irradiation of methanol:ammonia ice

Author

Caro, G. M. Munoz, Dartois, E., Boduch, P., Rothard, H., Domaracka, A., Jimenez-Escobar, A., Caro, G. M. Munoz, Dartois, E., Boduch, P., Rothard, H., Domaracka, A., and Jimenez-Escobar, A.

Abstract

The main goal of this work is to compare the effects induced in ices of astrophysical relevance by high-energy ions, simulating cosmic rays, and by vacuum ultraviolet (UV) photons. This comparison relies on in situ infrared spectroscopy of irradiated CH3OH:NH3 ice. Swift heavy ions were provided by the GANIL accelerator. The source of UV was a microwave-stimulated hydrogen flow discharge lamp. The deposited energy doses were similar for ion beams and UV photons to allow a direct comparison. A variety of organic species was detected during irradiation and later during ice warm-up. These products are common to ion and UV irradiation for doses up to a few tens of eV per molecule. Only the relative abundance of the CO product, after ice irradiation, was clearly higher in the ion irradiation experiments. For some ice mixture compositions, the irradiation products formed depend only weakly on the type of irradiation, swift heavy ions, or UV photons. This simplifies the chemical modeling of energetic ice processing in space., Comment: 9 pages, 9 figures, 2 tables, accepted in A&A

Published

2014

21. Processing of formic acid-containing ice by heavy and energetic cosmic ray analogues

Author

Bergantini, A., Pilling, S., Rothard, H., Boduch, P., Andrade, D. P. P., Bergantini, A., Pilling, S., Rothard, H., Boduch, P., and Andrade, D. P. P.

Abstract

Formic acid (HCOOH) has been extensively detected in space environments, including interstellar medium (gas and grains), comets and meteorites. Such environments are often subjected to the action of ionizing agents, which may cause changes in the molecular structure, thus leading to formation of new species. Formic acid is a possible precursor of pre-biotic species, such as Glycine (NH2CH2COOH). This work investigates experimentally the physicochemical effects resulting from interaction of heavy and energetic cosmic ray analogues (46MeV 58Ni11+) in H2O:HCOOH (1:1) ice, at 15 K, in ultrahigh vacuum regime, using Fourier transform infrared spectrometry in the mid-infrared region (4000-600 cm-1 or 2.5-12.5 microns). After the bombardment, the sample was slowly heated to room temperature. The results show the dissociation cross-section for the formic acid of 2.4x10^-13 cm2, and half-life due to galactic cosmic rays of 8x10^7 yr. The IR spectra show intense formation of CO and CO2, and small production of more complex species at high fluences.

Published

2014

22. Comparison of UV and high-energy ion irradiation of methanol:ammonia ice

Author

Caro, G. M. Munoz, Dartois, E., Boduch, P., Rothard, H., Domaracka, A., Jimenez-Escobar, A., Caro, G. M. Munoz, Dartois, E., Boduch, P., Rothard, H., Domaracka, A., and Jimenez-Escobar, A.

Abstract

The main goal of this work is to compare the effects induced in ices of astrophysical relevance by high-energy ions, simulating cosmic rays, and by vacuum ultraviolet (UV) photons. This comparison relies on in situ infrared spectroscopy of irradiated CH3OH:NH3 ice. Swift heavy ions were provided by the GANIL accelerator. The source of UV was a microwave-stimulated hydrogen flow discharge lamp. The deposited energy doses were similar for ion beams and UV photons to allow a direct comparison. A variety of organic species was detected during irradiation and later during ice warm-up. These products are common to ion and UV irradiation for doses up to a few tens of eV per molecule. Only the relative abundance of the CO product, after ice irradiation, was clearly higher in the ion irradiation experiments. For some ice mixture compositions, the irradiation products formed depend only weakly on the type of irradiation, swift heavy ions, or UV photons. This simplifies the chemical modeling of energetic ice processing in space., Comment: 9 pages, 9 figures, 2 tables, accepted in A&A

Published

2014

23. Formation of unsaturated hydrocarbons in interstellar ice analogs by cosmic rays

Author

Pilling, S., Andrade, D. P. P., da Silveira, E. F., Rothard, H., Domaracka, A., Boduch, P., Pilling, S., Andrade, D. P. P., da Silveira, E. F., Rothard, H., Domaracka, A., and Boduch, P.

Abstract

The formation of double and triple C-C bonds from the processing of pure c-C6H12 (cyclohexane) and mixed H2O:NH3:c-C6H12 (1:0.3:0.7) ices by highly-charged, and energetic ions (219 MeV O^{7+} and 632 MeV Ni^{24+}) is studied. The experiments simulate the physical chemistry induced by medium-mass and heavy-ion cosmic rays in interstellar ices analogs. The measurements were performed inside a high vacuum chamber at the heavy-ion accelerator GANIL (Grand Accel\'erat\'eur National d'Ions Lourds) in Caen, France. The gas samples were deposited onto a polished CsI substrate previously cooled to 13 K. In-situ analysis was performed by a Fourier transform infrared (FTIR) spectrometry at different ion fluences. Dissociation cross section of cyclohexane and its half-life in astrophysical environments were determined. A comparison between spectra of bombarded ices and young stellar sources indicates that the initial composition of grains in theses environments should contain a mixture of H2O, NH3, CO (or CO2), simple alkanes, and CH3OH. Several species containing double or triple bounds were identified in the radiochemical products, such as hexene, cyclohexene, benzene, OCN-, CO, CO2, as well as several aliphatic and aromatic alkenes and alkynes. The results suggest an alternative scenario for the production of unsaturated hydrocarbons and possibly aromatic rings (via dehydrogenation processes) in interstellar ices induced by cosmic ray bombardment., Comment: 14 pages, 10 figures, 4 tables. Accepted to be published in MNRAS

Published

2012

24. Formation of unsaturated hydrocarbons in interstellar ice analogs by cosmic rays

Author

Pilling, S., Andrade, D. P. P., da Silveira, E. F., Rothard, H., Domaracka, A., Boduch, P., Pilling, S., Andrade, D. P. P., da Silveira, E. F., Rothard, H., Domaracka, A., and Boduch, P.

Abstract

The formation of double and triple C-C bonds from the processing of pure c-C6H12 (cyclohexane) and mixed H2O:NH3:c-C6H12 (1:0.3:0.7) ices by highly-charged, and energetic ions (219 MeV O^{7+} and 632 MeV Ni^{24+}) is studied. The experiments simulate the physical chemistry induced by medium-mass and heavy-ion cosmic rays in interstellar ices analogs. The measurements were performed inside a high vacuum chamber at the heavy-ion accelerator GANIL (Grand Accel\'erat\'eur National d'Ions Lourds) in Caen, France. The gas samples were deposited onto a polished CsI substrate previously cooled to 13 K. In-situ analysis was performed by a Fourier transform infrared (FTIR) spectrometry at different ion fluences. Dissociation cross section of cyclohexane and its half-life in astrophysical environments were determined. A comparison between spectra of bombarded ices and young stellar sources indicates that the initial composition of grains in theses environments should contain a mixture of H2O, NH3, CO (or CO2), simple alkanes, and CH3OH. Several species containing double or triple bounds were identified in the radiochemical products, such as hexene, cyclohexene, benzene, OCN-, CO, CO2, as well as several aliphatic and aromatic alkenes and alkynes. The results suggest an alternative scenario for the production of unsaturated hydrocarbons and possibly aromatic rings (via dehydrogenation processes) in interstellar ices induced by cosmic ray bombardment., Comment: 14 pages, 10 figures, 4 tables. Accepted to be published in MNRAS

Published

2012

25. Radiolysis of H2O:CO2 ices by heavy energetic cosmic ray analogs

Author

Pilling, S., Duarte, E. Seperuelo, Domaracka, A., Rothard, H., Boduch, P., da Silveira, E. F., Pilling, S., Duarte, E. Seperuelo, Domaracka, A., Rothard, H., Boduch, P., and da Silveira, E. F.

Abstract

An experimental study on the interaction of heavy, highly charged, and energetic ions (52 MeV Ni^13+) with pure H2O, pure CO2 and mixed H2O:CO2 astrophysical ice analogs is presented. This analysis aims to simulate the chemical and the physicochemical interactions induced by heavy cosmic rays inside dense and cold astrophysical environments such as molecular clouds or protostellar clouds. The measurements were performed at the heavy ion accelerator GANIL (Grand Accelerateur National d'Ions Lourds in Caen, France). The gas samples were deposited onto a CsI substrate at 13 K. In-situ analysis was performed by a Fourier transform infrared (FTIR) spectrometer at different fluences. Radiolysis yields of the produced species were quantified. The dissociation cross sections of pure H2O and CO2 ices are 1.1 and 1.9E-13 cm^2, respectively. In the case of mixed H2O:CO2 (10:1) the dissociation cross sections of both species are about 1E-13 cm^2. The measured sputtering yield of pure CO2 ice is 2.2E4 molec/ion. After a fluence of 2-3E12 ions/cm^2 the CO2/CO ratio becomes roughly constant (~0.1), independent of the of initial CO2/H2O ratio. A similar behavior is observed for the H2O2/H2O ratio which stabilizes at 0.01, independent of the initial H2O column density or relative abundance., Comment: 13 pages, 9 figures, 4 tables. Accepted to be published in Astronomy and Astrophysics

Published

2010

26. Radiolysis of H2O:CO2 ices by heavy energetic cosmic ray analogs

Author

Pilling, S., Duarte, E. Seperuelo, Domaracka, A., Rothard, H., Boduch, P., da Silveira, E. F., Pilling, S., Duarte, E. Seperuelo, Domaracka, A., Rothard, H., Boduch, P., and da Silveira, E. F.

Abstract

An experimental study on the interaction of heavy, highly charged, and energetic ions (52 MeV Ni^13+) with pure H2O, pure CO2 and mixed H2O:CO2 astrophysical ice analogs is presented. This analysis aims to simulate the chemical and the physicochemical interactions induced by heavy cosmic rays inside dense and cold astrophysical environments such as molecular clouds or protostellar clouds. The measurements were performed at the heavy ion accelerator GANIL (Grand Accelerateur National d'Ions Lourds in Caen, France). The gas samples were deposited onto a CsI substrate at 13 K. In-situ analysis was performed by a Fourier transform infrared (FTIR) spectrometer at different fluences. Radiolysis yields of the produced species were quantified. The dissociation cross sections of pure H2O and CO2 ices are 1.1 and 1.9E-13 cm^2, respectively. In the case of mixed H2O:CO2 (10:1) the dissociation cross sections of both species are about 1E-13 cm^2. The measured sputtering yield of pure CO2 ice is 2.2E4 molec/ion. After a fluence of 2-3E12 ions/cm^2 the CO2/CO ratio becomes roughly constant (~0.1), independent of the of initial CO2/H2O ratio. A similar behavior is observed for the H2O2/H2O ratio which stabilizes at 0.01, independent of the initial H2O column density or relative abundance., Comment: 13 pages, 9 figures, 4 tables. Accepted to be published in Astronomy and Astrophysics

Published

2010

27. Radiolysis of ammonia-containing ices by energetic, heavy and highly charged ions inside dense astrophysical environments

Author

Pilling, S., Duarte, E. Seperuelo, da Silveira, E. F., Balanzat, E., Rothard, H., Domaracka, A., Boduch, P., Pilling, S., Duarte, E. Seperuelo, da Silveira, E. F., Balanzat, E., Rothard, H., Domaracka, A., and Boduch, P.

Abstract

Deeply inside dense molecular clouds and protostellar disks, the interstellar ices are protected from stellar energetic UV photons. However, X-rays and energetic cosmic rays can penetrate inside these regions triggering chemical reactions, molecular dissociation and evaporation processes. We present experimental studies on the interaction of heavy, highly charged and energetic ions (46 MeV Ni^13+) with ammonia-containing ices in an attempt to simulate the physical chemistry induced by heavy ion cosmic rays inside dense astrophysical environments. The measurements were performed inside a high vacuum chamber coupled to the heavy ion accelerator GANIL (Grand Accelerateur National d'Ions Lourds) in Caen, France.\textit{In-situ} analysis is performed by a Fourier transform infrared spectrometer (FTIR) at different fluences. The averaged values for the dissociation cross section of water, ammonia and carbon monoxide due to heavy cosmic ray ion analogs are ~2x10^{-13}, 1.4x10^{-13} and 1.9x10^{-13} cm$^2$, respectively. In the presence of a typical heavy cosmic ray field, the estimated half life for the studied species is 2-3x10^6 years. The ice compaction (micropore collapse) due to heavy cosmic rays seems to be at least 3 orders of magnitude higher than the one promoted by (0.8 MeV) protons . In the case of the irradiated H2O:NH3:CO ice, the infrared spectrum at room temperature reveals five bands that were tentatively assigned to vibration modes of the zwitterionic glycine (+NH3CH2COO-)., Comment: Accepted to be published in Astronomy and Astrophysics; Number of pages: 12; Number of Figures: 7; Number of Tables: 5

Published

2009

28. Radiolysis of ammonia-containing ices by energetic, heavy and highly charged ions inside dense astrophysical environments

Author

Pilling, S., Duarte, E. Seperuelo, da Silveira, E. F., Balanzat, E., Rothard, H., Domaracka, A., Boduch, P., Pilling, S., Duarte, E. Seperuelo, da Silveira, E. F., Balanzat, E., Rothard, H., Domaracka, A., and Boduch, P.

Abstract

Deeply inside dense molecular clouds and protostellar disks, the interstellar ices are protected from stellar energetic UV photons. However, X-rays and energetic cosmic rays can penetrate inside these regions triggering chemical reactions, molecular dissociation and evaporation processes. We present experimental studies on the interaction of heavy, highly charged and energetic ions (46 MeV Ni^13+) with ammonia-containing ices in an attempt to simulate the physical chemistry induced by heavy ion cosmic rays inside dense astrophysical environments. The measurements were performed inside a high vacuum chamber coupled to the heavy ion accelerator GANIL (Grand Accelerateur National d'Ions Lourds) in Caen, France.\textit{In-situ} analysis is performed by a Fourier transform infrared spectrometer (FTIR) at different fluences. The averaged values for the dissociation cross section of water, ammonia and carbon monoxide due to heavy cosmic ray ion analogs are ~2x10^{-13}, 1.4x10^{-13} and 1.9x10^{-13} cm$^2$, respectively. In the presence of a typical heavy cosmic ray field, the estimated half life for the studied species is 2-3x10^6 years. The ice compaction (micropore collapse) due to heavy cosmic rays seems to be at least 3 orders of magnitude higher than the one promoted by (0.8 MeV) protons . In the case of the irradiated H2O:NH3:CO ice, the infrared spectrum at room temperature reveals five bands that were tentatively assigned to vibration modes of the zwitterionic glycine (+NH3CH2COO-)., Comment: Accepted to be published in Astronomy and Astrophysics; Number of pages: 12; Number of Figures: 7; Number of Tables: 5

Published

2009

29. Collision induced fragmentation of fullerene clusters

Author

Manil, B., Boduch, P., Cassimi, A., Kamalou, O., Maunoury, L., Jensen, Jens, Zettergren, H., Manil, B., Boduch, P., Cassimi, A., Kamalou, O., Maunoury, L., Jensen, Jens, and Zettergren, H.

Published

2005

30. Implantation of multiply charged carbon ions in water ice

Author

Lv, X. Y., de Barros, A. L. F., Boduch, P., Bordalo, V., da Silveira, E. F., Domaracka, A., Fulvio, D., Hunniford, C. A., Langlinay, T., Mason, N. J., McCullough, R. W., Palumbo, M. E., Pilling, S., Rothard, H., Strazzulla, G., Lv, X. Y., de Barros, A. L. F., Boduch, P., Bordalo, V., da Silveira, E. F., Domaracka, A., Fulvio, D., Hunniford, C. A., Langlinay, T., Mason, N. J., McCullough, R. W., Palumbo, M. E., Pilling, S., Rothard, H., and Strazzulla, G.

Abstract

Context. Several objects in the Solar System like Europa, Ganymede and Callisto have frozen surface (main component: H2O). The associated thickness is bigger than the penetration depth of the relevant projectile ions. Additionally, other species such as H2O2, SO2 and CO2 have been detected on these surface. The formation mechanisms of these molecules are still under discussion. Aims. We present new experimental results on the implantation of 13Cq+ (q = 2, 3) ions at an energy of 30 keV in water ice at low temperatures (15 and 80 K). Experiments with multiply charged ions at energies of tens of keV are particularly relevant to simulating the complexity of the irradiation environment to which the surfaces of the icy moons in the outer solar system are exposed. Methods. The experiments were performed at the low energy ion beam facility ARIBE of GANIL in Caen (France). 30 keV 13Cq+ (q = 2, 3) ions have been used to bombard solid H,2O surface which were frozen at 15K and 80K. Fourier Transform Infrared Spectrometer (FTIR) was used to analyze the sample in the 5000 - 600 cm-1 (2-16.7 μm) region with a spectral resolution of 1 cm-1. Results. The results of our experiments indicate that implantation produces 13CO2 with yields in the range of 0.32-0.57 molecules ion-1. This yield seems to be independent of the temperature of the ices in the range studied. We have estimated the time scale necessary to accumulate by implantation of magnetospheric carbon ions the observed quantity of carbon dioxide on the surface of Europa, a Jovian moon. This time scale is of the order of 1.0-1.3x104 yrs which is higher than that evaluated for carbon dioxide production by other relevant processe