Systems Astrochemistry: A New Doctrine for Experimental Studies

Mason, Nigel J.; Hailey, Perry A.; Mifsud, Duncan V.; Urquhart, J. S.

doi:10.3389/fspas.2021.739046

Cited by 4 publications

(8 citation statements)

References 72 publications

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“…Moreover, our primary aim in this present study was to determine whether any changes in the physico-chemical evolution of an astrophysical ice undergoing electron irradiation could be induced solely via a change in the phase of the ice, thus necessitating the adoption of an OFAT approach. The results of this study confirm the importance of considering the effect of ice phase in determining the outcome of a radiation astrochemistry experiment, and so highlight the need to build this parameter into more exhaustive systems astrochemistry experiments [82].…”

Section: Astrochemical Implicationssupporting

confidence: 68%

“…This work is a typical example of a one-factor-at-a-time (OFAT) study, in which one experimental parameter (in this case, the phase of the ice under consideration) is varied and the results of such variation on the resultant physico-chemical evolution of the ice is analysed [81]. It has been suggested that such OFAT studies may not be ideal in revealing the true chemical complexity of an astrochemical reaction or process, and that statistically designed experiments and systems science approaches may be more appropriate [82].…”

Section: Astrochemical Implicationsmentioning

confidence: 99%

“…81 It has been suggested that such OFAT studies may not be ideal in revealing the true chemical complexity of an astrochemical reaction or process, and that statistically designed experiments and systems science approaches may be more appropriate. 82 Nevertheless, we consider our use of an OFAT approach to be justified, as a great deal of chemical complexity related to the radiolysis of CH 3 OH and N 2 O ices has already been revealed by previous studies. Moreover, our primary aim in this present study was to determine whether any changes in the physicochemical evolution of an astrophysical ice undergoing electron irradiation could be induced solely via a change in the phase of the ice, thus necessitating the adoption of an OFAT approach.…”

Section: Astrochemical Implicationsmentioning

confidence: 99%

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Comparative electron irradiations of amorphous and crystalline astrophysical ice analogues

Mifsud

Hailey

Herczku

et al. 2022

Phys. Chem. Chem. Phys.

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Section: Astrochemical Implicationssupporting

confidence: 68%

Section: Astrochemical Implicationsmentioning

confidence: 99%

Section: Astrochemical Implicationsmentioning

confidence: 99%

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Comparative electron irradiations of amorphous and crystalline astrophysical ice analogues

Mifsud

Hailey

Herczku

et al. 2022

Phys. Chem. Chem. Phys.

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“…Indeed, to the best of our knowledge, no previous study has included the RAI and Ih phases in such a comparative and systematic investigation. Our work therefore represents a progression in our understanding of the phase dependence of the radiation physics and chemistry of H 2 O astrophysical ices, thus allowing this parameter to be better incorporated into more exhaustive and relevant future experiments performed using a systems astrochemistry approach [47]. We have also interpreted our results in light of the new conclusions presented by Mifsud et al with regards to the role of hydrogen-bonds in impeding the radiolytic decay of crystalline ices [46].…”

Section: Introductionmentioning

confidence: 57%

“…However, fewer experiments have sought to investigate the effects of simultaneously changing multiple parameters on the resultant chemistry, despite this likely being more appropriate in terms of simulating astrophysical chemistry. Such an experimental approach is the basis of systems astrochemistry [47], and the data provided by this and similar studies will no doubt be useful in building up these more exhaustive and complete astrochemical experiments.…”

Section: Oh + Oh → H2o2mentioning

confidence: 94%

Laboratory experiments on the radiation astrochemistry of water ice phases

et al. 2022

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Water (H2O) ice is a 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. Graphical abstract

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Decoding the molecular complexity of the solar-type protostar NGC 1333 IRAS 4A

Quitián-Lara,

Fantuzzi,

Mason

et al. 2023

Monthly Notices of the Royal Astronomical Society

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The characterization of the molecular inventory of solar-type protostars is of crucial importance for a deep understanding of the chemical complexity underlying our cosmic origins. In this context, we present here the full millimetre line survey of the Class 0 protostellar object NGC 1333 IRAS 4A in the spectral bands at 3, 2, and 1.3 mm. In recognition of the powerful tool that unbiased spectral studies provide for investigating the chemistry and physics of star-forming regions, we provide a detailed description of the survey and the results of the analysis. We describe the identification of 1474 spectral lines belonging to 97 different molecular species, including complex organic molecules, which together cover the most ubiquitous chemical elements of life on Earth, namely carbon, hydrogen, nitrogen, oxygen, phosphorus, and sulphur. The abundances obtained herein are compared with the Class 0 protostellar objects L483 and L1527, and selected molecular ratios are used as tracers of physicochemical properties of the sources. Particularly, the dominance of oxygen-bearing species and the presence of distinct excitation temperature regimes support the attribution of NGC 1333 IRAS 4A as a hot corino featuring three physical components with distinguished and diverse chemical composition.

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Systems Astrochemistry: A New Doctrine for Experimental Studies

Cited by 4 publications

References 72 publications

Comparative electron irradiations of amorphous and crystalline astrophysical ice analogues

Comparative electron irradiations of amorphous and crystalline astrophysical ice analogues

Laboratory experiments on the radiation astrochemistry of water ice phases

Decoding the molecular complexity of the solar-type protostar NGC 1333 IRAS 4A

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